KR101444395B1 - Method and system of automatic intelligent control that can cope with emergency - Google Patents

Abstract

A disclosed technique relates to an intelligent automatic control method capable of coping with emergency and a system thereof. An intelligent automatic control method capable of coping with emergency includes the steps of: sensing the number of persons in a building by sensing units installed at each floor of the building; storing information about the sensed number of persons in a database every a predetermined period; sensing a fire caused in the building by using a fire sensor disposed in the building; reading out the information about the number of persons at a time point approximate to the time when the fire breaks out among the plural information about the number of persons stored in the database by a central control unit; and transmitting an emergency signal to the control room of an emergency team, wherein the emergency signal includes information about whether the fire breaks out, the number of persons at the time point approximate to the time when the fire breaks out and a view showing a structure of the building. Thus, a work of fighting a fire is performed at the initial stage with reference to the information about whether the fire breaks out in the building, the number of persons and the view showing the building structure, so that efficient relief work is induced, thereby preventing losses of lives.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an intelligent automatic control method and system,

The disclosed technique relates to an intelligent automatic control method and system for coping with emergency situations caused by a fire.

Early suppression of fire accidents is very helpful in reducing casualties and financial damage. For this reason, there are various control systems to cope with a fire in a building with a large population, such as a department store or a movie theater.

In one embodiment, there are a number of automatic control systems that monitor the occurrence of a fire by installing a CCTV in various places in a building or determine whether a fire has occurred by using various sensors and cope with a fire accident immediately.

On the other hand, such automatic control systems generally cope with a fire accident in itself when a fire occurs. For example, if it is judged that a fire has occurred in the automatic control system, a fire extinguishing device or a disaster prevention device such as a sprinkler can be controlled to suppress the fire.

However, it is a reality that there are not many buildings or places where a disaster prevention system is disposed, and even if disaster prevention is possible in itself, the level is somewhat lacking, and it is unreasonable to suppress the fire effectively .

Korean Patent Laid-Open No. 10-2011-0108497 (entitled "Automatic fire recognition alarm system using intelligent IP camera and method thereof") is known as an automatic control system for coping with a fire accident.

The disclosed technique is to provide a system and method for identifying the number of people in a building, suppressing a fire more efficiently, evacuating people, and responding to an emergency situation.

According to a first aspect of the present invention, there is provided a method for controlling a building, comprising the steps of sensing a number of persons in the building installed in each floor of a building, storing the number of persons according to the detected number of persons in a database A step of detecting a fire in the building using a fire detection sensor disposed in the building, a step of calling the number of people at a time point adjacent to a fire occurrence point among a plurality of persons information stored in the database, An intelligent automatic control method capable of emergency coping comprising the step of transmitting a rescue signal including a fire occurrence, a number of persons at a time point adjacent to the fire occurrence point, and a diagram showing a structure of the building to a control room of a rescue party .

According to a second aspect of the present invention, there is provided a method for managing a number of people in a building, the method comprising the steps of: detecting a number of people in the building, A fire detection sensor for detecting a fire occurring in a building and a number of persons at a time point adjacent to a fire occurrence point among a plurality of the number of persons information stored in the database when the fire occurs, And a central control unit for transmitting the figure of the number of persons and the structure of the building, which is stored in advance, to the control room of the emergency unit.

Embodiments of the disclosed technique may have effects that include the following advantages. It should be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, since the embodiments of the disclosed technology are not meant to include all such embodiments.

According to an embodiment of the disclosed technology, an intelligent automatic control method and system capable of emergency coping provides an effect of grasping the number of persons present in a building and transmitting the fact that the building is located in the building to an emergency unit .

In addition, there is an advantage that a fire-fighting operation can be performed more quickly by detecting the area where a fire occurs in the building.

It also provides the effect of preventing casualties by continuously transmitting the flow of the floating population in the building.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a flowchart of an intelligent automatic control method capable of emergency response according to one embodiment of the disclosed technique.
2 is a block diagram of an intelligent automatic control system capable of emergency response according to one embodiment of the disclosed technique.
3 is an implementation diagram of an intelligent automatic control system capable of emergency response according to one embodiment of the disclosed technique.
4 is a view showing an embodiment of a sensing unit for sensing the number of people in the disclosed technique.
5 is a view showing the number of people information stored in the database in the disclosed technique.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terms first, second, A, B, etc., may be used to describe various components, but the components are not limited by the terms, but may be used to distinguish one component from another . For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that the singular < RTI ID = 0.0 > terms < / RTI > used herein should be interpreted to include a plurality of representations unless the context clearly dictates otherwise. And "comprises ", when used in this specification, specify the presence of stated features, numbers, steps, operations, elements, parts, or combinations thereof, Or combinations thereof, as a matter of course.

Before describing the drawings in detail, it is to be clarified that the division of constituent parts in this specification is merely a division by main functions of each constituent part. That is, two or more constituent parts to be described below may be combined into one constituent part, or one constituent part may be divided into two or more functions according to functions that are more subdivided.

In addition, each of the constituent units described below may additionally perform some or all of the functions of other constituent units in addition to the main functions of the constituent units themselves, and that some of the main functions, And may be carried out in a dedicated manner. Accordingly, the presence or absence of each component described in this specification should be interpreted as a function.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a flowchart of an intelligent automatic control method capable of emergency response according to one embodiment of the disclosed technique. Referring to FIG. 1, an intelligent automatic control method capable of emergency coping includes a step 110 of detecting a number of people in the building installed in each floor of a building, a step of detecting a number of people according to the detected number of persons, A step 130 of detecting a fire in the building using a fire detection sensor disposed inside the building, a step 130 of detecting a fire occurring in the building using a plurality of persons information stored in the database, (Step 140) of sending information on the number of people at the time of the fire, the number of persons at the time of occurrence of the fire, the number of people at the time of occurrence of the fire, and the structure of the building to the control room of the emergency service (150).

In step 110, the sensing unit senses the number of people in the building. The sensing department senses the people in the building and identifies the number of people. In one embodiment, it can detect people in a particular room or room in a building.

On the other hand, the sensing unit is installed for each layer of the building. Generally, people are not located on only one floor of the building, so it is desirable that the sensing unit be installed on every floor of the building. And, of course, it is also installed in the lobby or corridor of the building.

Meanwhile, the sensing unit used in step 110 can use a sensor or a camera capable of counting the number of people on the basis of the presence or absence of a person. For example, the sensing unit may include at least one of an image sensor, an operation sensor, an access sensor, an ID card reader, a fingerprint reader, an RFID reader, an infrared camera, and an operation recognition camera.

In step 120, the number of persons according to the detected number of persons is stored in the database according to a predetermined period. The database stores the number of people information according to a period previously inputted from the automatic control system or the central system of the building. Alternatively, if the number of persons information is transmitted according to a predetermined period set by the sensing unit, the database may be stored in order of transmission.

Here, the number of persons information means information including details of the presence of a person in the sensing unit. The database stores information on the number of persons detected for each floor and room of the building. The number of people information stored for each floor and room will be described later with reference to FIG.

In step 130, a fire is detected in the building using a fire detection sensor disposed inside the building. Since the fire detection sensor can not know in advance where the fire will occur, it is preferable to arrange a plurality of fire detection sensors in the building as a whole.

Meanwhile, the fire detection sensor senses flame, smoke, and heat in determining whether a fire has occurred. For example, the fire detection sensor includes at least one of a smoke detection sensor, a flame detection sensor, and a heat generation sensor.

In an embodiment, when smoke is generated in a hot-tub room in a building, the smoke sensor disposed in the hot-tub room may sense the fire and determine that a fire has occurred. Alternatively, a flame detection sensor disposed in the office may sense a flame generated in the office and judge that a fire has occurred.

In step 140, the central control unit retrieves the number of persons at a time point adjacent to the fire occurrence point among a plurality of the number of persons information stored in the database. Here, the central control unit may use an automatic control system for controlling the power of the building or the operation of the electric power facility. For example, it may be a device or device that controls and manages the power supply of a lamp or an air conditioner.

In step 140, when the central control unit recognizes that a fire has occurred through the fire detection sensor in step 130, the central control unit retrieves the number of persons at a time point adjacent to the time point of the fire among a plurality of the number of persons information stored in the database.

Here, it is assumed that the central control unit and the database are connected to each other in advance. For example, they may be connected to each other through a communication line pre-wired to each other.

In one embodiment, if the number of people information is stored at every hour in the database and a fire occurs at about 1:20 pm, the central control unit stores the number of persons information stored at 1:00 PM among the plurality of persons information stored every square- . ≪ / RTI >

If it is determined in step 140 that a fire has occurred in the building through the fire detection sensor, the central control unit controls the alarm unit to generate an alarm. For example, a siren or an alarm may be sounded to indicate that a fire has occurred in the vicinity.

Since it is the wisest way to minimize the casualties that may occur even before the fire is suppressed, the disclosed technology controls the alarm device to generate an alarm as the fire occurs.

In step 140, the central control unit may control the disaster prevention equipment to perform a predetermined disaster prevention work. In fact, if a fire occurs, 119 or paramedics will be dispatched to a team that specializes in disaster prevention work. Even if they dispatch as soon as possible, some time will inevitably occur depending on available personnel or road conditions.

As with other kinds of emergency situations, early suppression of fire accidents is a great help in minimizing the damage. Therefore, if possible, it is desirable to control the disaster prevention equipment installed in the building and carry out the disaster prevention work a little bit. For example, the sprinkler can be operated to relieve the flames somewhat.

In step 150, the central control unit transmits the rescue signal corresponding to the fire occurrence to the emergency room control room. Here, the structural signal transmitted by the central control unit includes a diagram showing the occurrence of a fire in a building, information on the number of people at a time when the fire occurs, and a structure of the building. In step 150, the rescue signal including the above information is transmitted to the emergency unit.

Meanwhile, in step 150, the central control unit further includes a communication unit for transmitting the rescue signal to the emergency room control room. And transmits the rescue signal to the control room of the emergency unit using the communication unit.

The communication unit transmits the rescue signal in the form of data through a predetermined wireless communication network. For example, it can be transmitted using a widely used mobile communication network such as 3G or 4G. Alternatively, it is also possible to transmit using Ethernet.

In addition, the rescue signal can be transmitted to a server of the emergency unit or a rescue terminal of the emergency unit. In general, a server or a terminal can be connected to each other via a mobile communication network and exchange data as described above. Thus, the structure signal can be transmitted in this way.

In one embodiment, the central control unit may transmit the rescue signal to a smartphone of a paramedic. Paramedics can receive a first aid signal on a smartphone, identify the location of the fire on the screen, the number of people in the building, and the structure inside the building before arriving at the fire site.

The step 150 further includes transmitting the number of persons stored in the database to the control room of the emergency unit after transmitting the rescue signal. Generally, when a fire occurs in a building, evacuation signals or announcements are sent to the inside of the building to evacuate people inside.

For example, people on the second floor can evacuate through a building exit to recognize the evacuation signal and avoid a fire. This can lead to some confusion as people move around inside the building, and if it is wrong, it can lead to human accidents, so it is necessary to know how people in the building are moving and where there are a relatively large number of people.

In order to prevent the above problem, in step 150, even after transmitting the rescue signal according to the occurrence of the fire, the person information is continuously detected and transmitted to the emergency room control room. For example, if the rescue signal is transmitted at 1 pm, the number of persons stored in the database can be continuously transmitted at intervals of one minute.

On the other hand, in the control room of the emergency unit receiving the rescue signal, it is determined where the building where the fire occurred is located according to the rescue signal, and at the same time, where the people are located in the building, It is possible to perform the fire fighting work and the life saving structure more efficiently.

2 is a block diagram of an intelligent automatic control system capable of emergency response according to one embodiment of the disclosed technique. And Figure 3 is an implementation diagram of an intelligent automatic control system capable of emergency response according to one embodiment of the disclosed technique.

Referring to FIGS. 2 and 3, the intelligent automatic control system capable of emergency response includes a sensing unit 210 disposed at each floor of a building to sense the number of people in the building, a number of persons according to the sensed number of persons, A fire detection sensor 230 for detecting a fire occurring in the building, and a plurality of persons information information stored in the database when the fire occurs, And a central control unit 240 for transmitting the fire information, the number of people at the adjacent time, and the structure of the building, which are stored in advance, to the control room of the emergency unit.

The sensing unit 210 senses the number of people in the building. The sensing unit 210 senses people located in the building and confirms how many people are in the building. Typically, there is at least one room in each floor of a building. For example, there may be rooms 101 and 102 on the first floor, and rooms 201 and 202 on the second floor. Therefore, it is preferable that the sensing unit 210 is disposed in each room existing in each floor of the building.

Meanwhile, the sensing unit 210 can use a sensor or a camera capable of counting the number of people based on the presence of a person. For example, the sensing unit may include at least one of an image sensor, an operation sensor, an access sensor, an ID card reader, a fingerprint reader, an RFID reader, an infrared camera, and an operation recognition camera.

The database 220 stores the number of persons according to the number of persons detected by the sensing unit 210 according to a predetermined period. The database 220 stores the number of people information according to a predetermined period. Alternatively, if the sensing unit 210 transmits the number-of-persons information according to a predetermined period, the database 220 may store the number-of-persons information as it is transmitted.

Here, the number of persons information means information including the details detected by the sensing unit 210. The period for storing the number of persons information is input from a control unit installed in the building. For example, it may be input from a control unit of an automatic control system that automatically controls the entire building.

Meanwhile, the database 220 stores the number of people for each floor and room of the building. That is, each of the number-of-persons information transmitted from the plurality of sensing units 210 arranged for each room is separately stored and stored. The number of people information stored for each floor and room will be described later with reference to FIG.

Meanwhile, the database 220 may be included in the central control unit 240. That is, the central control unit 240 may include the database 220. [ For example, if the central control unit is a computer that performs a predetermined process, the database may be a storage medium of the computer.

The fire detection sensor 230 is disposed inside the building to detect a fire in the building. Since the fire detection sensor 230 does not know in advance where the person is located in the building, the fire detection sensor 230 can not know in advance where the fire in the building will occur, so that a plurality of fire detection sensors 230 are disposed in the building as a whole . That is, it is preferable that the sensing unit 210 and the fire detection sensor 230 are disposed so as to be able to detect the inside of the building.

Meanwhile, the fire detection sensor 230 detects flame, smoke, and heat in determining whether a fire has occurred. For example, the fire detection sensor 230 includes at least one of a smoke detection sensor, a flame detection sensor, and a heat generation sensor.

In an embodiment, when smoke is generated in a hot-tub room in a building, the smoke sensor disposed in the hot-tub room may sense the fire and determine that a fire has occurred. Alternatively, a flame detection sensor disposed in the office may sense a flame generated in the office and judge that a fire has occurred.

The central control unit 240 retrieves the number of persons at a time point adjacent to the fire occurrence point among a plurality of the number of persons information stored in the database 220. [ Here, the central control unit 240 is connected to the database 220 and the fire detection sensor 230. Therefore, it is possible to retrieve the number-of-persons information from the database 220 as necessary, and receive detection information according to the occurrence of a fire from the fire detection sensor 230.

Meanwhile, the central control unit 240 may use an automatic control system for controlling the operation of the building or the power facility. For example, it is possible to add a function to cope with a fire accident in a processor that controls the electric power of a lamp or an air conditioner.

When the central control unit 240 recognizes that a fire has occurred through the fire detection sensor 230, the central control unit 240 determines the number of persons at a time point adjacent to the time of the fire among the plurality of persons information stored in the database 220 .

In one embodiment, if the number of persons information is stored in the database once every 10 minutes and a fire occurs at 2:22 PM, the central control unit determines the number of persons stored at 2:20 PM among the plurality of persons information stored in the database . ≪ / RTI >

Meanwhile, the central control unit 240 includes an alarm device for generating an alarm according to the occurrence of a fire. If the fire detection sensor 230 detects a fire in the building and transmits it to the central control unit 240, the central control unit 240 can generate an alarm by controlling the alarm. For example, a siren or an alarm may be sounded to indicate that a fire has occurred in the vicinity.

In addition, when a fire occurs in the building, the central control unit 240 can perform a predetermined disaster prevention work by controlling the disaster prevention equipment. For example, the sprinkler can be controlled to lower the ignition point, or the shut-off wall can be operated to control the supply of oxygen to the point where the fire occurs.

When a fire actually occurs, 119 or paramedics dispatched a crew who specializes in disaster prevention work, which will inevitably take time. However, fire incidents, as with other kinds of emergency situations, can be a great help in minimizing the damage. Therefore, if possible, it is desirable to control the disaster prevention equipment installed in the building and carry out the disaster prevention work a little bit.

Meanwhile, the central control unit 240 transmits the rescue signal according to the fire to the emergency room control room. Here, the structural signal transmitted by the central control unit 240 includes information indicating the occurrence of a fire, the number of people at a time point when a fire occurs, and the structure of the building. The central control unit 240 transmits a rescue signal including the above information to the emergency unit.

Meanwhile, the central control unit 240 further includes a communication unit for transmitting the rescue signal to the emergency room control room. And transmits the rescue signal to the control room of the emergency unit using the communication unit.

Here, the rescue signal is transmitted in the form of data through a predetermined wireless communication network. For example, it can be transmitted using a mobile communication network widely used in the public, such as 3G or 4G. Alternatively, it is also possible to transmit using Ethernet.

In addition, the central control unit 240 can transmit the rescue signal to the server of the emergency unit or the rescue terminal of the emergency unit. In general, a server or a terminal can be connected to each other via a mobile communication network and exchange data as described above. Thus, the structure signal can be transmitted in this way.

In one embodiment, the central control 240 may send the rescue signal to the smartphone of the paramedic. Paramedics can receive a first aid signal on a smartphone, identify the location of the fire on the screen, the number of people in the building, and the structure inside the building before arriving at the fire site.

Accordingly, in the control room of the emergency unit receiving the rescue signal, it is possible to determine where the building where the fire occurred is located according to the rescue signal, and also to know where people are located in the building and to refer to the drawing showing the structure of the building, It is possible to perform the fire fighting work and the life saving structure more efficiently.

On the other hand, the central control unit 240 transmits the number-of-people information continuously stored in the database to the control room of the emergency unit after transmitting the rescue signal. Generally, when a fire occurs in a building, evacuation signals or announcements are sent to the inside of the building to evacuate people inside.

For example, people gathered in a large auditorium on the third floor may be aware of the evacuation signal and evacuate through a building exit to avoid a fire. In such a case, the paramedics preparing for the rescue operation need to know how the people in the building are moving and where there are a relatively large number of people, and notify the crews.

Accordingly, the central control unit 240 continuously detects the number of persons even after transmitting the rescue signal according to the fire, and transmits the detected information to the emergency room control room. For example, if the rescue signal is transmitted at 2 pm, the number of persons stored in the database can be continuously transmitted at intervals of 5 minutes. Of course, if paramedics are dispatched and the fire accident is completely resolved and all people are evacuated, the transmission of the number of people information is terminated.

In a case where a small number of people are still left in the building, it is difficult to determine the position where the paramedics should enter due to the fire. Then, the central control unit 240 continuously informs the number information to the smartphone of the paramedic It is advantageous to perform fast and accurate lifesaving without unnecessary waste of time and labor.

4 is a view showing an embodiment of a sensing unit for sensing the number of people in the disclosed technique. Referring to FIG. 4, the sensing unit senses a person in the building and grasps the number of people.

As described above with reference to FIGS. 1 to 3, the sensing unit includes at least one of an image sensor, a motion sensor, an access sensor, an ID card reader, a fingerprint reader, an RFID reader, an infrared camera, and an operation recognition camera.

Referring again to FIG. 4, at the entrance of a specific room in the building, an entrance / exit sensor is used to check that people are moving in and out. You can check how many people are in the room by checking the number of people coming in and out of each gate. The number of people is checked through the counter unit as shown in FIG.

On the other hand, it is possible to confirm whether or not there is a person in each place by using the motion detection camera disposed inside the room. As shown in FIG. 4, it is possible to detect the number of people based on the detection of the presence or absence of a person by place. The motion detection camera also uses the counter unit to check the number of people.

In this way, the sensing unit can detect the number of people by installing sensors or cameras capable of recognizing the number of people in each room of each floor in the building. Of course, the same can be detected in the lobby outside the room or in the waiting room.

5 is a view showing the number of people information stored in the database in the disclosed technique. Referring to FIG. 5, the type of the number of people information stored in the database can be confirmed.

In one embodiment, the number of persons information may be stored in the form of a table as in FIG. Since the number of persons information is information included in the rescue signal, the name, address, and number of persons information of the building are grasped so that the paramedics can more easily perform the rescue operation, and the date and time stored in the database are included. And information on the number of persons per room allocated for each floor.

In one embodiment, the paramedics may dispatch a large number of paramedics to the person # 201 where they are most located. Conversely, people may perform rescue work from a small room to perform lifeguards as quickly as possible. Alternatively, the rescue operation may be performed in the order close to the point where the fire occurred.

On the other hand, from the viewpoint of the owner or manager of the building, the rescue signal including the above-mentioned number of persons information can be transmitted to the emergency unit to induce efficient rescue activities. In the emergency unit, Fire fighting work and life saving work can be performed.

Although the intelligent automatic control method and system capable of emergency response according to an embodiment of the disclosed technology has been described with reference to the embodiments shown in the drawings for the sake of understanding, it is merely an example, and those skilled in the art It will be understood that various modifications and equivalent embodiments may be possible. Accordingly, the true scope of protection of the disclosed technology should be determined by the appended claims.

110: Detecting the number of people in the building 120: Storing the number of people in DB
130: Fire detection 140: Information on the number of persons at the time of fire adjacent to the time of fire load 150: Rescue signal transmission
210: sensing unit 220:
230: fire detection sensor 240: central control unit

Claims (16)

Detecting a number of people in the building by a sensing unit installed in each floor of the building;
Storing the number of persons according to the detected number of persons in a database according to a predetermined period;
Detecting a fire in the building using a fire detection sensor disposed inside the building;
The central control unit retrieving the number of persons at a time point adjacent to the fire occurrence point among a plurality of the number of persons information stored in the database; And
And transmitting a rescue signal including the number of persons at the time of occurrence of the fire, the number of people at a time point adjacent to the fire point, and the building structure to the control room of the emergency unit,
Wherein the sensing unit includes at least one of an image sensor, a motion sensor, an access sensor, an ID processor, a fingerprint reader, an RFID reader, an infrared camera,
Wherein the fire detection sensor includes at least one of a smoke detection sensor, a flame detection sensor, and a heat generation sensor,
The step of transmitting the rescue signal to the emergency room control room comprises:
And transmitting the rescue signal to the server of the control room or the rescue party terminal of the rescue party using the communication unit mounted on the central control unit, To the control room of the intelligent automatic control system. delete delete 2. The method of claim 1,
The method according to claim 1, wherein the number of persons is classified according to the floor and the room of the building. delete delete 2. The apparatus of claim 1,
The intelligent automatic control method according to any one of claims 1 to 3, wherein the alarm is generated by controlling an alarm device when a fire is generated in the building. 2. The apparatus of claim 1,
The intelligent automatic control method according to claim 1, wherein, when it is determined that a fire has occurred in the building, an emergency countermeasure can be performed in which a predetermined disaster prevention work is performed by controlling a disaster prevention facility. A sensing unit arranged for each floor of the building and sensing the number of people in the building;
A database for storing the number of persons according to the detected number of persons according to a predetermined period;
A fire detection sensor for detecting a fire occurring in the building; And
The fire information, the number of people at the adjacent time point, and the structure of the building previously stored in the database, when the fire occurs, from the plurality of the number of persons information stored in the database, To the control room of the emergency unit,
Wherein the sensing unit includes at least one of an image sensor, a motion sensor, an access sensor, an ID processor, an RFID reader, an infrared camera, and an operation recognition camera,
Wherein the fire detection sensor includes at least one of a smoke detection sensor, a flame detection sensor, and a heat generation sensor,
The central control unit,
And a communication unit that communicates with the control room of the emergency unit, wherein the communication unit transmits the resterilization signal to a server of the control room or an emergency rescue terminal of the emergency unit, and after the rescue signal is transmitted, An intelligent automatic control system capable of fetching the number of persons stored and transmitting the information to the control room of the emergency unit. delete delete 10. The method according to claim 9,
An intelligent automatic control system capable of emergency countermeasures for storing the number of persons for each floor and room of the building. delete delete 10. The apparatus of claim 9,
The intelligent automatic control system according to claim 1, further comprising an alarm device, wherein, when it is determined that a fire has occurred in the building, an emergency cope can be generated by controlling the alarm device to generate an alarm. 10. The apparatus of claim 9,
An intelligent automatic control system capable of an emergency countermeasure to perform a predetermined disaster prevention work by controlling a disaster prevention facility disposed in the building when a fire is generated in the building.

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