KR101478691B1 - System and method for delaying spread of fire in intelligent building - Google Patents

Abstract

The present invention relates to a system and a method for monitoring fire and, more specifically, to a system and a method for delaying the spread of fire in an intelligent building, capable of: generating fire spread prevention information including air-conditioning control information to control an air-conditioning device to rapidly discharge smoke to the outside while delaying fire considering a traveling direction of the fire and the smoke when the fire is detected; properly delaying the fire and discharging the smoke by controlling the air-conditioning device according to the generated fire spread prevention information; and analyzing and guiding a safe fire exit on which the fire spread prevention information is reflected.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an intelligent building,

The present invention relates to a diffusion delaying system and method, and more particularly, to a diffusion delaying system and method for delaying a fire in consideration of the direction of fire and smoke when a fire is detected, And controls the air conditioner in accordance with the generated fire spread prevention information to analyze and guide the safe escape route reflecting the fire spread prevention information while appropriately performing the delay of the fire and the discharge of the smoke Intelligent Building Fire Diffusion Delay System.

Fire is one of the indispensable tools for mankind and causes fire. The fire not only takes away the lives and property of individuals, but also brings great economic losses to the country. Various types of fire related systems have been developed and applied to various fields such as cultural properties, buildings, mountains, and vehicles in order to prevent such fire as much as possible or to cope with a fire quickly. Examples of the fire related system include a fire alarm system, a fire monitoring system, a fire fighting system, and a evacuation guidance system.

Generally, a fire monitoring system includes a sensor unit for detecting heat, smoke, and flame generated in the early stage of a fire, and a buzzer, a siren, or the like is generated when the sensor unit detects fire, smoke, A warning unit for informing people that a fire has occurred and a fire door window opening device for opening a fire window of the fire detected area, a sprinkler for spraying water at an initial fire position, and an evacuation guide device for enabling early evacuation. Device unit and the like.

The flue gas window opening device is for rapidly discharging the smoke generated during a fire to the outside of the building to prevent people from suffocating due to smoke.

Normally, the flue gas window opening device is constituted such that it is provided with a sensor part and is opened when a fire is detected, or is opened under the control of a central control part which detects a fire through a sensor part.

 However, the unreasonable opening of the window can create a path of fire, which can quickly spread to other places.

In addition, the general evacuation guidance device has a problem that it is difficult to recognize a safe evacuation route because the evacuation guiding device is composed of a simple lamp or a voice guidance which does not reflect a fire area.

Even if it is guided by the voice reflecting the area where the fire occurred, there is a problem that it is difficult to safely evacuate people by simply guiding the evacuation route to people who are uninvited by the fire.

Patent Publication No. 10-2012-0108316 (2012.10.05) Patent Registration No. 10-102273 (Mar.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide fire prevention information that includes air conditioning control information for controlling an air conditioner to quickly discharge smoke while delaying a fire in consideration of the direction of fire and smoke when a fire is detected, A fire escape delay and evacuation guidance function for analyzing and guiding a safe evacuation route reflecting the above-mentioned fire spread prevention information while controlling the air conditioner according to the generated fire spread prevention information, Control system and method.

According to another aspect of the present invention, there is provided an intelligent building fire retarding system comprising: a plurality of fire monitoring areas, A plurality of sensor portions including sensors of the sensor; A data collecting unit collecting sensor data by the fire monitoring area through the sensor unit; And an air conditioner management unit for controlling the air conditioner to control the air conditioner for the ventilation control zone of the inputted fire prevention setting information to be installed in the fire monitoring area in an optional ventilation control zone unit Management; And the sensor data of the fire monitoring area collected through the data collecting unit to analyze the occurrence of a fire, a fire surveillance zone where a fire occurs, the direction of the fire, and the direction of the smoke to analyze the location of the fire, And fire prevention setting information including air conditioner control information for judging the ventilation control zone which can delay the spread of fire according to the direction of the smoke and controlling the air conditioner of the ventilation control zone, And a fire situation analyzing unit provided to the management unit.

Wherein the sensor unit includes a temperature sensor unit having a temperature sensor for detecting the temperature of the fire monitoring zone and outputting the detected temperature sensor data; And a smoke concentration sensor for detecting the smoke concentration of the fire monitoring area, and for outputting the detected smoke concentration sensor data.

The sensor member, the fire monitoring CO ₂ sensor provided and outputs the detected CO ₂ concentration sensor data, the CO ₂ concentration sensor for detecting the CO ₂ concentration in the zone; A humidity sensor unit having a humidity sensor for detecting the humidity of the fire monitoring area and outputting the detected humidity sensor data; And a flame sensor for detecting a flame of the fire monitoring area, and a flame sensor for outputting detected flame sensor data.

The air conditioner includes: a duct forming an air passage between the ventilation control zones and the outside in the fire monitoring area; A ventilation window connected to the duct in units of the ventilation control zone and controlled so as to be connected to the ventilation control zone and the ventilation duct of the duct; And a fan installed in an arbitrary ventilation control zone unit so that the air on the duct is rapidly discharged to the outside.

Wherein the fire situation analyzer comprises: a fire analyzer for analyzing the sensor data of the fire monitoring area to determine whether or not the fire has occurred; A fire zone analyzer for analyzing at least one fire monitoring zone where a fire occurs when the fire is analyzed through the fire analyzer; A smoke progress direction analyzer for analyzing the direction of smoke movement by at least two sensor units for detecting smoke concentration sensor data of the sensor data; A fire progress direction analyzing unit for analyzing the progress direction of the fire by two or more sensor units in which an anomaly is detected among the temperature of the sensor data and the flame sensor data; And a ventilation control zone including a fire monitoring zone information corresponding to the analyzed fire monitoring zone information, a fire progress direction information, and a fire monitoring zone corresponding to smoke progress direction information, And a fire prevention setting unit for generating fire prevention information including the information of the control zone and the air conditioner control information of the ventilation control zone and outputting the generated information to the building management unit.

The fire situation analyzing unit analyzes whether the sensor data collected by each fire monitoring area of the collected sensor data, sensor data of each fire monitoring area is out of the measurement range, And a sensor abnormality analyzing unit for determining whether or not the data is out of the pattern of the sensor unit and judging the abnormality of the sensor unit.

The fire situation analysis unit may further include a fire growth rate analyzing unit for analyzing a fire growth rate by detecting a rate of transition to adjacent fire monitoring zones in a fire monitoring zone detected at the time of fire detection, The ventilation control zone to be controlled is determined in consideration of the growth rate.

The system includes a camera unit having a plurality of cameras installed at an arbitrary position in the fire monitoring area and photographing the fire monitoring areas and outputting image data, Wherein the fire situation analyzing unit further analyzes the image analysis information to determine whether or not the fire has occurred, and analyzes a smoke progress direction and a fire progress direction.

The system comprising: an output configured to be located at any location in the fire surveillance area to guide the escape route; And a fire escape prevention setting information input by the fire situation analyzing unit, the control unit searches for a safe escape route at each location where the output unit is installed, and searches each escape route retrieved through the corresponding output unit And an evacuation guidance unit for outputting and guiding the evacuation guidance.

Wherein the output unit comprises: an audio device for outputting a guidance voice by evacuation; And a display device for displaying the escape route corresponding to the position of the output unit in at least one of a character and a graphic.

The system is configured to: set alert levels in normal, attention, attention, alert and critical stages according to data values of sensor data; set different alerts for each stage; And an alarm unit for receiving an alarm and generating an alarm corresponding to the alarm level information through the output unit and a separate alarm device.

The system includes: a mobile communication terminal in which a mobile communication terminal installed with an evacuation guidance application when a fire is detected transmits a push message for forcibly activating the evacuation guidance application, activates the evacuation guidance application, and activates the evacuation guidance application through the evacuation guidance application And an evacuation guidance application driver for displaying an evacuation route to be inputted and guiding it.

According to another aspect of the present invention, there is provided a fire propagation delay method for an intelligent building fire spread delay system, comprising: a sensor data collection process for collecting sensor data for each fire monitoring zone and providing the sensor data to a fire situation analyzer; A fire monitor process that analyzes the collected sensor data to monitor the occurrence of a fire; Analysis of fire situation Fire detection process to analyze the fire monitoring area, the direction of the fire and the direction of the smoke when the fire is detected. Analysis of Fire Situation Determine a ventilation control zone that can delay the spread of fire according to the location of the fire, the direction of the fire, and the direction of the smoke, and provide the air conditioner control information for controlling the air conditioner of the ventilation control zone A fire prevention setting information generating step of generating fire prevention setting information including the fire prevention setting information; And a fire delaying process for delaying a fire by controlling the air conditioner according to the fire spread prevention setting information.

The fire analysis process may include analyzing the collected sensor data to analyze a fire surveillance zone where a fire occurs; Analyzing the collected sensor data and analyzing a fire monitoring area of two or more sensor units for outputting sensor data reflecting a fire environment according to a fire, and analyzing a fire direction of the fire; And analyzing the collected sensor data and analyzing a fire monitoring area of two or more sensor units for outputting sensor data reflecting the smoke concentration according to the fire to analyze the direction of smoke movement, .

The fire situation analyzing process may include analyzing whether or not the sensor abnormality analyzing unit inputs sensor data for each fire monitoring area of the collected sensor data, whether or not sensor data of each fire monitoring area is out of the measurement range, And a sensor abnormality analyzing step of determining whether or not there is an abnormality in the sensor unit by judging whether or not the data is out of the pattern at the time of occurrence of a fire or not, And a sensor abnormality notification message including the sensor abnormality notification message.

The fire situation analysis process may further include a fire growth rate analysis process for analyzing a fire growth rate by detecting a rate at which a fire growth rate analyzing unit is transferred to an adjacent fire monitoring zone in a fire monitoring zone detected at the time of fire detection, And the ventilation control zone to be controlled is determined in consideration of the fire growth rate in the fire spread prevention setting process.

The method may further include: analyzing image data input through a plurality of cameras and outputting image analysis information, wherein the image analysis information is further reflected in the fire situation analysis process, And the direction of the smoke progress and the direction of the fire progress are analyzed.

The method includes: searching for a safe evacuation route at each location where the output unit is installed based on image data input through a camera and a fire prevention setting information input from the fire situation analyzer, And outputting and outputting the information through the output unit.

The present invention controls at least one of an air conditioning system and an air conditioning system of a fire monitoring area in an intelligent building, which is a fire surveillance area where a fire occurs when a fire is detected, delays fire spreading by blocking a fire surveillance area, In other areas, the smoke can be quickly ventilated, minimizing suffocation by smoke from evacuees, ensuring the visibility of the evacuation route, and allowing people to evacuate more quickly and safely .

In addition, the present invention analyzes sensor data collected through various sensors such as temperature, flame, smoke and humidity, and image data collected through a camera such as CCTV to determine the direction of fire, fire, and smoke It is possible to perform more accurate fire detection, more accurate control of the air conditioner in accordance with the direction of the fire and the direction of smoke, and more accurate and safe evacuation guidance.

Further, the present invention provides a display device and an audio device in an intelligent building in an intelligent building, guides the evacuation route through both the visual and auditory devices through the display device and the audio device, guides each evacuation route in each area It is possible to accurately recognize people who are guided in the area and evacuate to a precise evacuation route.

In addition, the present invention induces an intelligent building fire evacuation guidance application to be installed in a mobile communication terminal such as a smart phone of people in an intelligent building, allows the building fire evacuation guidance application to be driven in the background, The evacuation guidance application is forcibly activated to provide the three-dimensional evacuation information in the building through the mobile communication terminal, so that the user can quickly evacuate the evacuation route.

1 is a view showing the construction of a fire spread delay system of an indubit building according to the present invention.
FIG. 2 is a view showing a configuration of an air conditioning management unit of a fire spread delay system of an intelligent building according to the present invention.
3 is a diagram illustrating a configuration of a fire escape path analysis unit of a fire spread delay system of an intelligent building according to the present invention.
4 is a diagram illustrating a configuration for associating with existing fire related legacy systems according to the present invention.
FIG. 5 is a view showing an example of directions of smoke and fire according to the sensor arrangement structure of a zone in the fire diffusion delay system of an intelligent building according to the present invention.
6 is a view showing an example of the operation of an air conditioner of a fire spread delay system of an intelligent building according to the present invention.
7 is a flowchart illustrating a method of delaying fire spread of an intelligent building according to the present invention.
FIG. 8 is a flowchart illustrating a method of evacuating a fire spread delay method of an intelligent building according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a configuration and operation of a fire spread delay system of an intelligent building of the present invention will be described with reference to the accompanying drawings, and a fire diffusion delay method in the system will be described.

FIG. 1 is a view showing the construction of a fire spread delay system of an inducement building according to the present invention, and FIG. 5 is a view showing a fire diffusion delay system of an intelligent building according to the present invention, FIG. 6 is a view showing an example of the operation of the air conditioner of the fire spread delay system of the intelligent building according to the present invention. 1, 5, and 6. FIG.

1, a fire spread delay system of an intelligent building includes a plurality of sensor units 10, a data collecting unit 20, a fire situation analyzing unit 40, a fire alarm unit 50 and a building management unit 80 The evacuation guiding unit 60, the evacuation guiding application driving unit 70, and the output unit 90 according to the embodiment of the present invention.

First, the area inside the intelligent building (hereinafter referred to as "fire monitoring area") according to the present invention is divided into a plurality of fire monitoring areas for monitoring fire by an arbitrary area, And a plurality of ventilation control zones are divided into a plurality of ventilation control zones. The fire monitoring zone and the ventilation control zone may be configured to coincide with each other and at least two fire monitoring zones may be included in one ventilation control zone.

The sensor unit 10 includes a temperature sensor unit 11 installed in each of the fire monitoring zones to measure temperature and output temperature sensor data in units of fire monitoring zones, A CO ₂ sensor unit 13 for measuring CO ₂ concentration and outputting CO ₂ smoke concentration sensor data, a humidity sensor unit 14 for measuring humidity and outputting humidity sensor data, And at least a temperature sensor unit 11 and a smoke concentration sensor unit 12 of the flame sensor unit 15 for detecting the flame sensor data. The sensor unit 10 may be a Ubiquitous Sensor Network (USN).

The data collecting unit 20 has information on the sensor unit 10 mapped to the fire monitoring zone information and the fire monitoring zone information. The sensor collecting unit 20 collects sensor data in real time through the sensor units 10, By the fire monitoring area and time. That is, output sensor data may be configured as shown in Table 1 below.

Contents Remarks One 14-character date / time information 20140530163627 2 Sensor ID Information 3 Sensor type information (integer Temperature sensor (1)
Smoke density sensor (2)
Humidity detector (3) 4 Sensor value information (integer) 5 Sensor location information (fire monitoring area information) 1123, etc.

The image processing unit 30 includes a camera unit 31 having a plurality of cameras installed in an arbitrary area in the fire monitoring area to output image data of an image of the corresponding area, And provides image analysis information, which is obtained by analyzing the collected image data, to the fire situation analyzing unit 40 and the evacuation guiding unit 60.

The fire alarm unit 50 is divided into five levels as shown in Table 2 below, and different alarms are set according to each step, and an alarm corresponding to the inputted alarm level information is generated.

step Step Definition Contents Remarks One normal Normal temperature, smoke, humidity The monitoring 2 Attention 20% increase in average sensor value and threshold value range Requires close observation of sensor changes 3 caution 50% increase in average sensor value and threshold value range Perception of fire risk,
Need precise analysis 4 boundary 80% increase in average sensor value and threshold value range Pre-fire, on-site response 5 serious The value of threshold for each sensor Fire-fighting action

For example, when the average temperature is 20 ° C and the threshold temperature is 45 ° C, it is judged to be a caution step when the temperature is raised to 32.5 ° C.

The fire situation analysis unit 40 includes a fire analysis unit 41, a fire zone analysis unit 42, a smoke progress direction analysis unit 43, a fire direction analysis unit 64, a fire growth rate analysis unit 45, The sensor abnormality analyzing unit 46 and the fire spread prevention setting unit 47 to analyze the sensor data input through the data collecting unit 20 according to the present invention to monitor whether or not the fire is monitored according to the fire monitoring area, The direction of the smoke, the direction of the fire, the fire detection zone judgment of the fire, the alarm level judgment and the sensor having the abnormality are detected and the analysis information corresponding thereto is generated and outputted.

More specifically, the fire analysis unit 41 comprehensively analyzes input sensor data to monitor whether a fire occurs in an arbitrary fire monitoring area. The fire analysis unit 41 has a threshold value for judging whether or not a fire has occurred, and monitors the fire status by comparing the sensor values of the sensor data with threshold values. For example, a temperature threshold of 45 ° C may be applied and a smoke concentration threshold of 2% / foot.

When a fire is detected during monitoring, the fire zone analyzing unit 42 extracts fire monitoring zone information of sensor data as shown in Table 1 to determine a fire monitoring zone and outputs the analysis information.

The smoke progress direction analyzing unit 43 analyzes the inputted sensor data and tracks the fire surveillance zones where the smoke concentration sensor value influenced by the fire smoke exceeds a predetermined threshold value to analyze the direction of the smoke, Outputs analysis information. 5, for example, the smoke progress direction analyzing unit 43 detects the sensor units 10-1, 10-4, 10-5, and 10-6 of the fire monitoring zones exceeding the threshold value, (3) of the smoke (2) through the sensor units (10-1, 10-4, 10-5, 10-6). Of course, in adjacent sensor units 10 of the sensor units 10-1, 10-4, 10-5, and 10-6, sensor data having a sensor value that approximates or exceeds a threshold value will be collected.

In analyzing the direction of the smoke, the smoke flow direction analyzer 43 analyzes the smoke diffusion characteristics and applies a smoke generation prediction model according to the direction of the fire of the input combustible.

Smoke moves in the building in various ways. Basically, it expands due to temperature and moves quickly to move to a space that is not divided into interlayer compartments such as air duct, elevator shaft, staircase, and service duct, , Or a gap between the curtain wall and the floor floor slab.

The smoke progress direction analyzing unit 43 calculates the smoke mass flow rate (Kg / m) as shown in the following equation (1) and the smoke volume calculation formula and smoke layer height calculation The theory is applied to calculate smoke generation.

Where p is the perimeter of the flame (m), Y is the bottom height of the smoke layer from the floor (m), p _o is the air density in the atmosphere (1.22 kg / m ² at 17 ° C), T _o ' The absolute temperature (290 K), T _f 'is the absolute temperature of the flame in the combustion volume (1100 K), and g is the gravitational acceleration (9.81 m / s ² ).

Here, ρ _S is the smoke density at T ° C (density of the air in the air ρ _o (air density at 1.22 kg / m ³ at an ambient temperature of 17 ° C.))

In addition, the generation of smoke during a fire is greatly affected by the amount of heat generated by the fire and the characteristics of the combustion material. The amount of fuel consumed by the fire is represented by the following equation (3), and the smoke generation amount (Q) of the fuel is represented by the following equation (4).

Here, an M _t / t is the consumption of fuel, △ H _ch is the chemical heat of combustion (chemical heat of combustion) of fuel, ^o Q is an amount of heat generated in a fire.

Where yp is the smoke generation rate of the fuel. The smoke generation rate according to the fuel is shown in Table 3 below.

Combustible material Chemical combustion heat Smoke generation rate (yp) (kJ / kg) Wood (oak) 12,400 0.015 폴리 프로필렌 38,600 0.059 Nylon 27,100 0.075 PVC 5,700 0.172 PE 38,400 0.060

The calculation formula of the smoke layer of the smoke layer height calculation theory is divided into a steady state and an abnormal state. The height of the smoke layer in the steady state is calculated as shown in Equation (5), and the height of the smoke layer in the abnormal state is calculated as shown in Equation (6).

Z: Clear height (m), H: Ceiling height (m), t: Time (sec)

tg: Growth time (sec), Q: Heat release rate (kw), A: Cross sectional area (m2)

The flame height is calculated by the following equation (7).

: 화염높이(m),

: 대류에 의한 열방출(kw)
here,

: Flame height (m),

: Heat release by convection (kw)

The smoke generation amount Q is calculated by the following equation (8).

: 연기발생량(kg/s),

: 연기 경계면의 높이(m) here,

: Smoke generation amount (kg / s),

: Height of smoke interface (m)

: 화염높이(m),

: 연기발생량(m3/s),

: 밀도(kg/m3)

: Flame height (m),

: Smoke generation amount (m3 / s),

: Density (kg / m3)

When the smoke generation amount is calculated as described above, the smoke advancing direction analyzing unit 43 obtains the amount of gas sucked by the flame (i.e., the amount of smoke generation) by the following equation (9) Is calculated by the following equation (10). &Quot; (10) "

In Equation (9), there is established a direct proportional relationship between the size (P, m) of the perimeter of the fire and the height (Y, m) dp of the clean space.

Where A is the floor space of the compartment (m ² ), P is the perimeter of the fire, Y is the distance from the floor to the bottom of the smoke floor (m), t is the required time in seconds, g is the gravitational acceleration (9.8m / s ² ) ), The height of the cleanliness layer, and h is the height (m) of the building, room or compartment.

In addition, the smoke moving direction analyzing unit 43 calculates the amount of air entering the fire room by natural ventilation by applying Equation (11).

Where H is the height of the opening, A is the area of the opening, k is the proportional constant, T ₁ , T _{0 is the} average temperature inside and outside the chamber, V is the volume of the chamber, n: Number of ventilation per hour

In addition, the smoke progress direction analyzing unit 43 may reflect the image data input through the image processing unit 30 to determine the direction of the smoke.

The fire progress direction analyzing unit 44 analyzes the input sensor data to predict the progress direction of the fire, that is, the direction of the fire, and outputs the result.

The fire growth rate analyzer 45 analyzes the time information of the inputted sensor data and analyzes the rate at which the fire passes through the fire monitoring zones to analyze the growth rate of the fire. The growth rate analysis of fire can be applied to the evacuation.

The sensor abnormality determination unit 46 analyzes the sensor data collected by sensors to determine whether there is a measurement value or a value outside the measurement range is collected, It is judged that the corresponding sensor is broken. The sensor abnormality determination unit 46 determines whether or not the sensor unit 10 (10) having the sensor has identification information of the failure sensor and an e-mail or short message through a communication unit (not shown) ) Of the fire detection zone information.

The fire spread prevention setting unit 47 maps information on the ventilation control zones in which the air conditioner and the fire fighting device in the fire monitoring zone are installed and the fire monitoring zones in the respective ventilation control zones, The fire and smoke direction information analyzed through the analyzing unit 41, the fire zone analyzing unit 42, the smoke proceeding direction analyzing unit 43, and the fire direction analyzing unit 44 is reflected, The air conditioner control unit controls the air conditioner control information for each ventilation control zone to drive the air conditioner so that the smoke is rapidly discharged to the outside in the other areas And outputs the generated information to the building management unit 80 and the evacuation guidance unit 60. [

The building management unit 80 includes an air conditioning management unit 81 connected to the air conditioning system (not shown) and the fire fighting system (not shown) installed in the fire control area for each ventilation control area to control the air conditioning system and the fire fighting system, And a security management unit 82 for controlling the locking and unlocking of the doors and the like in the door. The air conditioner may include a duct passing through the entire space of the fire monitoring area, a smoke exhaust window installed on the duct in units of a ventilation control zone, and a fan. The fire extinguishing device may include a sprinkler, There will be. The air conditioning management unit 81 receives the fire prevention setting information from the fire situation analyzing unit 40, and controls the air conditioner and the fire fighting apparatus according to the air conditioner control information included in the fire prevention setting information. The security management unit 82 receives the evacuation route information from the evacuation guiding unit 60 and releases the locks on the doors corresponding to the evacuation route of the evacuation route information so that people can easily evacuate.

6, when a fire occurs in the fire monitoring zone 1, the fire situation analyzing unit 40 detects a fire in the fire monitoring zone 1 through the fire analyzing unit 41 something to do. If a fire occurs in the fire monitoring area 1, the smoke will flow into the duct through the fire window of the corresponding fire monitoring area 1 as shown in (a) and spread to the adjacent fire monitoring area 2 as shown in (b). Because smoke is faster than flame, smoke will spread first. If the smoke is diffused as shown in (b) of FIG. 2, the fire spread prevention setting unit 47 of the fire situation analysis unit 40 sets the fire prevention zone 1 in the fire monitoring zone 1 between the adjacent fire monitoring zones 2, It will generate fire prevention setup information that includes all of the windows closed, drives the fire fighting device of the fire monitoring zone 1, and the air conditioner control information to open both the fire monitoring zone 2 and the exhaust windows connected to the outside. By controlling in this way, the fire will be trapped in the fire monitoring zone 1 as shown in (c), delaying the spread of the fire, and allowing the smoke to be discharged quickly in other areas, thereby minimizing loss of life due to smoke.

The output unit 90 includes an audio device (not shown) for outputting a fire alarm, a guide for evacuation, and a display device (not shown) for guiding the fire alarm and evacuation guide textually or graphically. The output unit 90 receives the step-by-step alarm signal from the fire alarm unit 50, generates a corresponding alarm, inputs guidance information from the evacuation guide unit 60 to the evacuation guide unit 60, and outputs the guidance voice and information to the evacuation unit.

Based on the air conditioning control information for each ventilation control zone of the fire prevention setting information input from the fire situation analyzing unit 40 and the image analysis information input through the image processing unit 30, Searches the evacuation route that is not the direction of the smoke progression, provides evacuation route information for the retrieved evacuation route to the security management unit 82 of the building management unit 80, generates evacuation information by evacuation at each ventilation control zone location And guides the escape route through an output 90 in each ventilation control zone.

When the evacuation guidance application application 70 is installed in the fire surveillance area, that is, in a mobile communication terminal (not shown) possessed by people in the intelligent building, and the evacuation guidance application is automatically activated to receive the evacuation guidance push message, Transmits the evacuation guidance push message to the mobile communication terminal and performs data communication through the evacuation guidance application activated by the evacuation guidance push message to display the evacuation information in three dimensions to perform the evacuation guidance.

FIG. 2 is a view showing a configuration of an air conditioning management unit of a fire spread delay system of an intelligent building according to the present invention.

2, the air conditioning management unit 81 receives the fire prevention setting information, separates the air conditioner and the control information for each fire fighting apparatus contained in the fire prevention setting information A control unit 812 for receiving the control information of the flue gas window ventilation equipment through the receiving unit 8110 and controlling the ventilation window according to the control information of the ventilation window control unit, A fan driving unit 813 for receiving the fan control information from the receiving unit 811 and controlling the fan in accordance with the fan control information and the control unit 811 for receiving the control information from the control unit 811, And a fire device driver 814 for controlling the fire device.

3 is a diagram illustrating a configuration of a fire escape path analysis unit of a fire spread delay system of an intelligent building according to the present invention. The detailed configuration of the image processing unit 30 and the evacuation guide unit 60 of the fire diffusion delay system will be described with reference to FIG.

The image processing unit 30 includes an image collecting unit 32 for collecting and outputting a plurality of image data from a camera unit 31 having a plurality of cameras and an image analyzing unit 32 for analyzing the collected image data and outputting image analysis information (33).

The image analysis unit 33 includes a correction distance calculation unit 331 for analyzing input image data and calculating and outputting a correction distance, a control unit 331 for analyzing the input image data, and entering the arbitrary area in which the camera outputting the corresponding image data is installed And an evacuation characteristic analyzer 333 for analyzing and outputting the evacuation characteristics of the evacuees when a fire occurs. In order to more accurately determine the number of persons entering and exiting the area, the personnel analysis unit 332 drives each camera for photographing each entrance when the area has a single entrance or has a plurality of entrance, The number of people should be counted by integrally analyzing the image data inputted through the cameras.

The evacuation guidance unit 60 has the fire detection area, i.e., the path information for the intelligent fielding, the audible data for the escape route information, and the visual and stereoscopic data, Information from the information on the fire surveillance zone, the direction of the fire's progress and the direction of the smoke, and not the direction in which fire and smoke proceed in each of the fire surveillance zones, The evacuation route analyzing unit 61 searches the evacuation route, generates evacuation information for the evacuated evacuation route, and provides the evacuation route information to the security managing unit 82 of the building management unit 80, And generates guiding information from each position corresponding to the evacuation information, that is, evacuation which can escape to the outside from each fire monitoring area And an evacuation route guide unit 62 for outputting via the output unit 90.

4 is a diagram illustrating a configuration for associating with existing fire related legacy systems according to the present invention.

Referring to FIG. 4, the fire propagation delay system 100 of the present invention may be constructed as an independent system as described above, or may be a building energy management system (BEMS), which is a conventional legacy system, (200) that stores and manages sensor data collected through a fire alarm system (400), a fire alarm system (300), an evacuation guidance system (500), a USN (700), and a USN It might be.

7 is a flowchart illustrating a method of delaying fire spread of an intelligent building according to the present invention.

Referring to FIG. 7, when power is supplied to the system of the fire situation analyzing unit 40, the sensor data, the sensor data, and the image analysis information are collected through the data collecting unit 20, And starts monitoring the occurrence of a fire (S111).

When the monitoring is started, the fire situation analyzing unit 40 continuously collects sensor data, sensor data, and image analysis information continuously (S113).

When the data is collected and stored, the sensor abnormality analyzer 46 analyzes the sensor data collected first (S115) and determines whether there is a sensor that has failed (S117). That is, the sensor abnormality analyzing unit 46 determines whether all of the sensors are operating normally.

If there is a faulty sensor, the sensor abnormality analyzing unit 46 sends a sensor abnormality notification message including fire monitoring zone information, that is, position information and sensor information, to which the sensor unit 10 including the faulty sensor is installed, Or a short message service (SMS) message. For this, the sensor abnormality analyzing unit 46 should store at least one mail address for the manager and the mobile communication terminal telephone number.

If there is no faulty sensor, the fire analysis unit 41 analyzes the collected sensor data for each fire monitoring area to check whether a fire occurs in an arbitrary fire monitoring area (S121).

If a fire occurs during the fire occurrence monitoring, the fire zone analysis unit 42 determines a fire monitoring zone where the sensor unit 10 providing the fire occurrence sensor data is installed (S123).

If it is judged that the fire monitoring area where the fire occurs is determined, the fire monitoring area to be blocked is determined by analyzing the sensor data of the adjacent fire monitoring areas in order to delay the spread of the fire, and the blocking ventilation control area including the determined fire monitoring area is determined , An open ventilation control zone for venting the smoke diffused to the other fire monitoring zones except for the blocking ventilation control zone is determined (S125).

When the cut-off ventilation control zone and the open ventilation control zone are determined, the fire-spread prevention setting unit 47 generates the air-conditioning device control information for the air-conditioning units and the fire-fighting units installed in the determined cut-off ventilation control zone and the open ventilation control zone, Diffusion prevention setting information including smoke and fire progress direction information analyzed by the smoke progress direction analyzing unit 43 and the fire proceeding direction analyzing unit 44, (S127). Fire extinguishing induction system, fire extinguishing system, air conditioning system, and the like exist, the fire extinguishing prevention setting information may be transmitted to the evacuation guidance system and the air conditioning system so as to be interlocked with the legacy systems.

The building management unit 90 receiving the fire prevention setting information may control the corresponding air conditioners in accordance with the air conditioner control information included in the fire prevention setting information, After the area is shut off, the fire extinguishing device is driven to attempt extinguishment, and the open ventilation control areas are opened to externally connect and discharge the smoke (S129).

At the same time as the fire spread delay and the ventilation, the evacuation guide unit 60 analyzes the evacuation path based on the fire spread prevention setting information and provides the analyzed evacuation path information to the security management unit 82 of the building management unit 80, (Step S131). The evacuation guidance information is generated through the evacuation route through the output unit 90 (S131).

Upon the start of the evacuation, the fire situation analyzing unit 40 notifies the fire related organization that a fire has occurred (S133). The notification may be configured to be notified to the fire department or the like via the existing legacy system, or may be configured to be notified to the fire related organization.

FIG. 8 is a flowchart illustrating a method of evacuating a fire spread delay method of an intelligent building according to the present invention.

First, the evacuation guiding unit 60 analyzes the fire spread prevention setting information when the fire spread prevention setting information is received from the fire situation analyzing unit 40 (S211) The safety evacuation route in each fire surveillance area excluding the fire surveillance area adjacent to the progress direction is analyzed (S213). At this time, the evacuation guide unit 60 may receive the image analysis information output from the image processing unit 30, and may further analyze the safety evacuation path by reflecting the corrective distance information and the like included in the image analysis information.

When the safe evacuation route is analyzed, the evacuation guiding unit 60 judges whether there is a safe evacuation route by location (S215).

If there is a safe evacuation route, the evacuation guiding unit 60 determines the evacuation route as a safe evacuation route by location (S217). If there is a safe evacuation route, it is determined as a safe evacuation route by analyzing the lane evacuation route ).

When the safe evacuation route for each location is determined, the evacuation guide unit 60 outputs evacuation route guidance information to the corresponding output unit 90 at each location (S221). Then, the output unit 90 will guide the guidance information to the evacuation by location corresponding to the corresponding location, and display evacuation route guidance information in the form of characters and graphics.

Further, the evacuation guidance unit 60 may be configured to provide safety evacuation information to the evacuation guidance application driving unit when the safety evacuation route is determined. In this case, the evacuation guiding application driving unit 70 installs the evacuation guiding application and transmits the evacuation guiding push message to the mobile communication terminals driven in the background to activate the evacuation guiding application, and then provides evacuation guiding information through the evacuation guiding application something to do.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be easily understood. It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, it is intended to cover various modifications within the scope of the appended claims.

10: sensor part 11: temperature sensor part
12: smoke concentration sensor unit 13: CO ₂ sensor unit
14: humidity sensor unit 15: flame sensor unit
20: Data collecting unit 30: Image processing unit
31: camera unit 32: image collecting unit
33: Image analysis unit 40: Fire situation analysis unit
41: fire analysis section 42: fire zone analysis section
43: smoke direction analysis unit 44: fire direction analysis unit
45: fire growth rate analyzing unit 46: sensor abnormality analyzing unit
47: fire prevention setting section 50: fire alarm section
60: evacuation guidance unit 61: evacuation path analysis unit
62: evacuation guide portion
70: evacuation guidance application driver
80: building management unit 81: air conditioning management unit
82: security management unit 90: output unit
331: Fixed-distance identification unit 332: Personnel analysis unit
333: Evacuation characteristic analyzing unit 811: Receiver
812: a smoking window control unit 813: a fan driving unit
814:

Claims (18)

A plurality of sensors including a plurality of sensors installed in the fire monitoring area of the fire monitoring area divided into a plurality of fire monitoring areas and outputting sensor data according to a fire;
A data collecting unit collecting sensor data by the fire monitoring area through the sensor unit;
And an air conditioner management unit for controlling the air conditioner to control the air conditioner for the ventilation control zone of the inputted fire prevention setting information to be installed in the fire monitoring area in an optional ventilation control zone unit Management; And
The sensor data of each fire monitoring area collected through the data collection unit are analyzed to determine whether or not a fire has occurred, a fire surveillance zone where a fire occurs, the direction of the fire, and the direction of the smoke, The fire prevention setting information including the air conditioner control information for judging the ventilation control zone which can delay the spread of the fire according to the direction of the smoke and controlling the air conditioner of the ventilation control zone, And a fire situation analyzing unit,
The fire situation analyzing unit,
A fire analyzer for analyzing the sensor data for each fire monitoring area to determine whether or not the fire has occurred;
A fire zone analyzer for analyzing at least one fire monitoring zone where a fire occurs when the fire is analyzed through the fire analyzer;
A smoke progress direction analyzer for analyzing the direction of smoke movement by at least two sensor units for detecting smoke concentration sensor data of the sensor data;
A fire progress direction analyzing unit for analyzing the progress direction of the fire by two or more sensor units in which an anomaly is detected among the temperature of the sensor data and the flame sensor data; And
A ventilation control zone including a fire monitoring zone information corresponding to the analyzed fire monitoring zone information, a fire progress direction information, and a fire monitoring zone corresponding to smoke progress direction information, And a fire prevention prevention unit configured to generate fire prevention information including information on a zone and air conditioner control information of the ventilation control zone, and output the generated fire prevention information to the building management unit.
The method according to claim 1,
The sensor unit includes:
A temperature sensor unit having a temperature sensor for detecting the temperature of the fire monitoring zone and outputting the detected temperature sensor data; And
And a smoke concentration sensor unit having a smoke concentration sensor for detecting the smoke concentration of the fire monitoring area and outputting the detected smoke concentration sensor data.

3. The method of claim 2,
The sensor unit includes:
To the fire with a CO ₂ concentration sensor for detecting a CO ₂ concentration of the monitor area, and outputs the detected CO ₂ concentration sensor data CO ₂ sensor;
A humidity sensor unit having a humidity sensor for detecting the humidity of the fire monitoring area and outputting the detected humidity sensor data; And
Further comprising at least one of a flame sensor for detecting a flame of the fire monitoring area and a flame sensor for outputting detected flame sensor data.
The method according to claim 1,
The air-
A duct forming an air passage between the ventilation control zones and the outside in the fire monitoring area;
A ventilation window connected to the duct in units of the ventilation control zone and controlled so as to be connected to the ventilation control zone and the ventilation duct of the duct; And
And a fan installed in an arbitrary ventilation control zone unit for rapidly discharging the air on the duct to the outside.
delete The method according to claim 1,
The fire situation analyzing unit,
Whether or not the sensor data collected by each fire monitoring area of the collected sensor data, whether the sensor data of each fire monitoring area is out of the measurement range, Further comprising a sensor abnormality analyzing unit for determining whether or not the sensor unit is abnormal and determining whether there is an abnormality in the sensor unit.
7. The method according to claim 1 or 6,
The fire situation analyzing unit,
And a fire growth rate analyzing unit for analyzing the fire growth rate by detecting the rate of transition from the fire monitoring zone detected in the fire detection to the adjacent fire monitoring zones,
Wherein the fire prevention prevention setting unit determines a ventilation control zone to be controlled based on the fire growth rate.
The method according to claim 1,
And a camera unit installed at an arbitrary position in the fire monitoring area and having a plurality of cameras for photographing the fire monitoring areas and outputting image data. The image analyzing unit analyzes the image data input through the cameras and outputs image analysis information The image processing apparatus according to claim 1,
The fire situation analyzing unit,
Wherein the image analysis information is further reflected to determine whether or not the fire has occurred, and the smoke progress direction and the fire progress direction are analyzed.
9. The method of claim 8,
An output unit configured at any position of the fire monitoring area to guide the escape route; And
A safe evacuation route at each location where the output unit is installed is searched based on the video data input through the camera and the fire prevention setting information input from the fire situation analyzing unit, and each retrieved evacuation route is output through the corresponding output unit And an evacuation guidance unit for guiding the evacuation of the intelligent building.
10. The method of claim 9,
The output unit includes:
An audio device for outputting a guidance voice by voice evacuation; And
And a display device for displaying the escape route corresponding to the position of the output unit in at least one of a character and a graphic and guiding the escape route.
delete 10. The method of claim 9,
When a fire is detected, a push message for forcibly activating the evacuation guidance application is transmitted to the mobile communication terminal where the evacuation guidance application is installed and operated, thereby activating the evacuation guidance application, and the evacuation guidance application, Further comprising: an evacuation guidance application driver configured to display and guide the evacuation guidance application.
A sensor data collection process in which the data collector collects sensor data for each fire monitoring area and provides the sensor data to the fire situation analyzer;
A fire monitor process that analyzes the collected sensor data to monitor the occurrence of a fire;
Analysis of fire situation Fire detection process to analyze the fire monitoring area, the direction of the fire and the direction of the smoke when the fire is detected.
Analysis of Fire Situation Determine a ventilation control zone that can delay the spread of fire according to the location of the fire, the direction of the fire, and the direction of the smoke, and provide the air conditioner control information for controlling the air conditioner of the ventilation control zone A fire prevention setting information generating step of generating fire prevention setting information including the fire prevention setting information; And
And a fire delaying process of delaying a fire by controlling the air conditioner according to the fire spread prevention setting information.
14. The method of claim 13,
The fire analysis process includes:
A fire monitoring area analysis step of analyzing the collected sensor data to analyze a fire monitoring area where a fire occurs;
Analyzing the collected sensor data and analyzing a fire monitoring area of two or more sensor units for outputting sensor data reflecting a fire environment according to a fire, and analyzing a fire direction of the fire; And
Analyzing the collected sensor data and analyzing a fire monitoring area of two or more sensor units for outputting sensor data reflecting smoke concentration according to a fire and analyzing the progress direction of the smoke, A method of delaying fire spread of a building.
15. The method of claim 14,
The fire situation analysis process includes:
Whether or not the sensor abnormality analyzing unit inputs the sensor data for each fire monitoring area of the collected sensor data, whether or not the sensor data of each fire monitoring area is out of the measurement range, And a sensor abnormality analyzing step of determining whether or not an abnormality exists in the sensor unit,
And a sensor abnormality notification message including the fire monitoring zone information and the sensor information for the sensor unit in which the abnormality is found, to the manager.
16. The method according to claim 14 or 15,
The fire situation analysis process includes:
And a fire growth rate analyzing process for analyzing the fire growth rate by detecting a rate at which the fire growth rate analyzing unit is transferred from the fire monitoring zone detected in the fire detection zone to the adjacent fire monitoring zones,
Wherein the ventilation control zone to be controlled is determined in consideration of the fire growth rate in the fire spread prevention setting process.
15. The method of claim 14,
And analyzing image data inputted through a plurality of cameras and outputting image analysis information,
Wherein the image analysis information is further reflected in the fire situation analysis process to determine whether or not the fire has occurred, and the smoke progress direction and the fire progress direction are analyzed.
15. The method of claim 14,
The evacuation guidance unit searches the safe evacuation route at each location where the output unit is installed based on the video data input through the camera and the fire spread prevention setting information input from the fire situation analyzing unit and transmits each retrieved evacuation route through the corresponding output unit Further comprising the steps of: (a) outputting and outputting a warning message to the intelligent building;

Images