JP2006268495A - Fire monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To specify a fire point position in case of a fire for accurately and surely carrying out life-saving and fire-extinguing activities. <P>SOLUTION: This fire monitoring system is provided with a plurality of sensors 4, which are arranged on a ceiling face 3 of a fire monitoring objective room 2 to detect temperature or smoke density of the fire monitoring objective room 2 in the occurrence of a fire for outputting a detection result as fire information, and an information processing part 5 receiving the fire information outputted from the respective sensors 3 and calculating and specifying a fire position based on the fire information and previously stored positional information of the respective sensors 4. The fire point position can be accurately determined based on the fire point positional information outputted from the information processing part 5, and consequently, life saving and fire extinguishing operation and the like can be carried out precisely and properly. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a fire monitoring system, and in particular, it is possible to accurately grasp a fire situation by specifying a fire point position and a heat source heat generation rate, and to quickly perform lifesaving and fire fighting activities based on the grasped information. Relates to possible fire monitoring systems.

  In general, a fire becomes larger with the passage of time. Therefore, if a fire can be detected at an early stage and an alarm can be issued, the residents in the building can quickly move to evacuation. In addition, the fire brigade can rush early, so fire fighting and rescue activities can be conducted before the fire spreads.

  However, the fire brigade must access the fire spot from the outside of the building and perform fire fighting / rescue activities depending on the situation. In order to carry out these fire fighting activities safely and accurately, the fire section It is indispensable to accurately grasp the situation (fire point position and fire scale). Furthermore, in the investigation after the fire, it is important to specify the source of the fire (fire point) and the fire spread route.

  Many of the sensors currently in common use are installed at a rate of one per sensing area (floor area), so it is possible to identify the fire area (area), but the fire point (point) Can not be identified. Furthermore, since it only has a function of generating a fire signal when the temperature, smoke density, radiant heat, or the like of the hot airflow becomes a predetermined value or more, it is impossible to grasp the current situation in the vicinity of the sensor.

  An example of a fire monitoring system using a sensor is provided with a flame detector and a CCD camera installed so that the monitored area of the flame detector is in the field of view, and the fire point position is determined from the image of the CCD camera. (See, for example, Patent Document 1).

  As another example, there has been proposed a flame detector and a scanning flame detector which are configured to obtain the position of a fire point based on fire position information from the scanning flame detector. (For example, see Patent Document 2.)

  Furthermore, as another example, a configuration has been proposed in which determination information as to whether or not the smoke has reached a dangerous level in the fire chamber is proposed from the temperature information of the temperature sensor installed on the ceiling surface. (For example, refer to Patent Document 3).

Furthermore, as another example, what is configured to calculate the fire growth rate from the temperature information of the temperature sensor installed on the ceiling surface and to notify the stay limit state from the fire growth rate has been proposed (for example, (See Patent Document 4).
JP 2001-34864 A JP 2000-353286 A JP 2002-8155 A JP 2004-246542 A

  By the way, among the various fire monitoring systems configured as described above, those described in Patent Documents 1 and 2 can determine the position of the fire point, Since combustibles block the flame in the space where articles are accumulated, it can be used only in a space with a high ceiling (8 m or more).

  Moreover, although what is described in patent document 3 can obtain the judgment information of whether the smoke has reached the dangerous level, it does not aim at specifying the fire point. In addition, since the temperature distribution of the hot air current cannot be taken into account, it is impossible to grasp the exact fire scale. Therefore, fire fighting activities cannot be performed safely and accurately.

  Furthermore, although what is described in patent document 4 can obtain the judgment information as to whether or not the fire room has reached the stay limit state, it is not intended to specify the fire point. In addition, since the temperature distribution of the hot air current cannot be taken into account, it is impossible to grasp the exact fire scale. Therefore, fire fighting activities cannot be performed safely and accurately.

  The present invention has been made in view of the above-described conventional problems. When a fire occurs, the fire point position and the heat source heat generation rate can be specified, and the situation of the fire can be accurately grasped. The purpose of this is to provide a fire monitoring system that can perform fire fighting activities such as lifesaving and fire fighting safely and accurately.

The present invention employs the following means in order to solve the above problems.
That is, the invention according to claim 1 is provided on a ceiling surface of a fire monitoring target room, and detects a temperature or smoke concentration of the fire monitoring target room and outputs it as fire information when a fire occurs, An information processing unit that receives fire information output from a sensor and calculates and identifies a fire point position based on the fire information and position information of each sensor stored in advance is provided. To do.

  According to the fire monitoring system of the present invention, it is possible to specify the position of a fire point when a fire occurs, so that the fire brigade can select the shortest route to the fire point or easily find the source of the fire in the investigation after the fire. Or can be specified. In addition, since it is possible to display the trajectory of the hot spot and to calculate the moving speed, it is possible to predict the fire spreading direction.

  The invention according to claim 2 is the fire monitoring system according to claim 1, wherein any four sensors are selected from the plurality of sensors, the fire information output from the selected four sensors, The hot spot position is calculated and specified based on the position information of the four sensors stored in the information processing unit.

  According to the fire monitoring system of the present invention, since the fire point position can be specified by processing the fire information from the four sensors by the information processing unit, the time required for specifying the fire point position is shortened. It is possible to grasp the exact fire point position in a short time.

  The invention according to claim 3 is the fire monitoring system according to claim 1 or 2, wherein the information processing unit is configured to store fire information output from the sensor and position information of each sensor stored in advance. And a heat source heat generation rate is calculated based on the height of the ceiling surface of the fire monitoring target room and the identified fire spot position information.

  According to the fire monitoring system of the present invention, an accurate fire source heat generation rate can be obtained based on the identified fire point position information, and the fire source area can be estimated from the fire source heat generation rate, It is also possible to grasp the speed of fire expansion from the relationship with the elapsed time. Furthermore, it is also possible to estimate the amount of watering required for fire extinguishing from the heat source heat generation rate and the fire source area.

  The invention according to claim 4 is the fire monitoring system according to any one of claims 1 to 3, wherein the fire spot position information or the fire source heat generation speed information output from the information processing unit is received and received. On the basis of the information, a control unit is provided for controlling the operation of watering equipment, smoke exhausting equipment installed on the ceiling surface of the fire monitoring target room, and fire prevention equipment installed on the partition wall of the fire monitoring target room. It is characterized by that.

  According to the fire monitoring system of the present invention, it is possible to control the operation of the watering facility, the smoke exhausting facility, and the fire prevention facility by the control unit based on the fire spot position information or the fire source heat generation speed information output from the information processing unit. As a result, fire fighting can be performed accurately and quickly in the event of a fire.

  The invention according to claim 5 is the fire monitoring system according to claim 4, wherein the watering facility opens and closes a plurality of watering heads installed on a ceiling surface of the fire monitoring target room and each watering head. It comprises a control valve, and the opening / closing operation of each control valve is controlled by the control unit.

  According to the fire monitoring system of the present invention, it is possible to accurately grasp the fire spread direction and the fire scale based on the specified fire spot position information and fire source heat generation speed information, so the watering head located in the fire spread direction is selected. Thus, the control valve can be opened early, or the control valve can be opened by selecting the watering head so as to surround the fire point. Also, if the fire spreads faster than expected, the watering head can be selected to open the control valve so as to surround the fire point in multiple layers. Therefore, it is possible to reliably prevent the spread of fire.

  The invention according to claim 6 is the fire monitoring system according to any one of claims 1 to 5, wherein the control unit is installed in a fire monitoring room disposed at a position remote from the fire monitoring target room. In the fire monitoring room, the fire information output from the sensor to the control unit, the sensor position information, the identified fire point position information, the fire source heat generation speed information, the operation information of the watering equipment, the exhaust The operation information of the smoke equipment and the operation information of the fire prevention equipment are remotely monitored.

  According to the fire monitoring system of the present invention, by setting up a fire monitoring room on the first floor, basement, etc., which is easy to approach from outside, in the fire monitoring room, fire information, sensor position information, specified fire point position Information, fire source heat generation rate information, etc. can be grasped accurately. Therefore, it becomes easy to establish fire fighting tactics for lifesaving and fire fighting activities. Also, in large-scale merchandise stores and skyscrapers where the distance from the fire monitoring room to the fire point is large, accurately convey fire information that changes from time to time to firefighters who are extinguishing fire near the fire point. Is possible. Therefore, fire extinguishing and rescue operations can be performed safely and accurately.

  As described above, according to the fire monitoring system according to claim 1 of the present invention, the fire point position can be specified in the event of a fire, so that the fire brigade has the shortest route to the fire point. The source of the fire can be easily selected in the post-fire investigation. In addition, since it is possible to display the trajectory of the hot spot and to calculate the moving speed, it is possible to predict the fire spreading direction.

  Moreover, according to the fire monitoring system of claim 2 of the present invention, the fire point position can be specified by processing the fire information from the four sensors by the information processing unit, so the fire point position is specified. It is possible to reduce the time required for the operation. Therefore, an accurate fire point position can be grasped in a short time, and in the event of a fire, lifesaving and fire extinguishing activities can be performed quickly.

  Furthermore, according to the fire monitoring system of the third aspect of the present invention, an accurate fire source heat generation rate can be obtained based on the identified fire spot position information. Accordingly, it is possible to estimate the fire source area from the heat source heat generation rate, or to grasp the fire expansion rate from the relationship between the heat source heat generation rate and the elapsed time. It is also possible to estimate the amount of watering required for fire extinguishing from the heat source heat generation rate and the fire source area.

  Furthermore, according to the fire monitoring system of claim 4 of the present invention, based on the fire point position information or the fire source heat generation rate information output from the information processing unit, the control unit sprays water, smoke exhausting equipment, fire prevention The operation of the equipment can be controlled. Therefore, in the event of a fire, water can be reliably sprayed where it needs to be sprayed, smoke can be started as needed, fire doors can be closed, etc. It can be carried out.

  Furthermore, according to the fire monitoring system of the fifth aspect of the present invention, it is possible to accurately grasp the fire spread direction and the fire scale based on the identified fire spot position information and fire source heat generation rate information. Therefore, it is possible to select the watering head located in the fire spreading direction and open the control valve early, or to select the watering head so as to surround the fire point and open the control valve. In addition, when the fire expansion is faster than expected, the watering head can be selected so as to surround the fire points in multiple layers, and the control valve can be opened, and the spread of fire can be reliably prevented.

  Furthermore, according to the fire monitoring system of claim 6, by installing a fire monitoring room on the first floor, basement, etc., which is easy to approach from outside, in the fire monitoring room, fire information, sensor position information, The identified fire point position information, fire source heat generation speed information, etc. can be accurately grasped. Therefore, it becomes easy to establish fire fighting tactics for lifesaving and fire fighting activities. Also, in large-scale merchandise stores and skyscrapers where the distance from the fire monitoring room to the fire point is large, accurately convey fire information that changes from time to time to firefighters who are extinguishing fire near the fire point. It is possible to perform fire fighting and rescue activities safely and accurately.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an embodiment of a fire monitoring system according to the present invention. This fire monitoring system 1 is provided on a ceiling surface 3 of a fire monitoring target room 2 of a building, and a predetermined fire is generated when a fire occurs. A sensor 4 that detects information, and an information processing unit 5 that calculates and identifies a fire point position and a heat source heat generation rate based on fire information output from the sensor 4 are provided.

  The sensors 4 are installed at a plurality of locations on the ceiling surface 3 of the fire monitoring target room 2 so as to form a lattice pattern at predetermined intervals vertically and horizontally. Each sensor 4 detects predetermined fire information (thermal air temperature, smoke concentration, etc.) when a fire occurs in the fire monitoring target room 2, and transmits the detected fire information to the information processing unit 5. .

  The sensor 4 is not particularly limited as long as it can detect the occurrence of a fire, but a temperature sensor or a smoke concentration sensor is effective for accurately detecting fire information without being affected by an obstacle or the like. . The temperature sensor detects the temperature of the hot air flow generated by the fire, and the smoke density sensor detects the smoke density generated by the fire, and transmits the detected fire information to the information processing unit 5.

  The information processing unit 5 is configured by a computer including a CPU, a ROM, and a RAM, for example. The information processing unit 5 receives the fire information transmitted from each sensor 4 and calculates and specifies the fire point position based on the fire information and the position information of each sensor 4 stored in advance. It functions as a fire point heat generation rate calculation unit that calculates and identifies a heat source heat generation rate based on the fire point position detection unit and the fire point position specified by the fire point position detection unit.

  Information such as the position information of each sensor 4, the fire information from each sensor 4, the fire spot position information obtained by the information processing unit 5, and the heat source heat generation rate information is transmitted via the information processing unit 5 to the fire monitoring target room 2. Is transmitted to the fire monitoring room 6 installed at a position (1st floor, basement, etc.) remote from the station and displayed on the display means (monitor, etc.) of the information output unit 7 of the fire monitoring room 6.

 The fire information displayed on the display means of the fire monitoring room 6 allows the fire brigade to select the shortest route to the fire point or to identify the source of the fire in the investigation after the fire. In addition, since the trajectory of the hot spot can be displayed and the moving speed can be calculated, the fire spread direction can also be predicted. Furthermore, by specifying the heat source heat generation rate, an accurate heat source heat generation rate can be obtained, and the area of the fire source can be estimated, or the rate of fire expansion can be determined from the relationship between the heat source heat generation rate and the elapsed time. It becomes possible to do. Furthermore, the amount of water spray required for extinguishing fire can be estimated from the heat source heat generation rate and the fire source area.

  A watering facility 8 is installed on the ceiling surface 3 of the fire monitoring target room 2. The watering equipment 8 includes a plurality of watering heads 9 that are installed on the ceiling surface 3 at predetermined intervals, a control valve 10 that is provided in each watering head 9 and opens and closes each watering head 9, and each watering head 9. A water supply tank 12 (water supply pump), which is a water supply source for supplying water via a pipe 11, and a control unit 13 (control panel) for controlling the opening / closing operation of each control valve 10.

  The control unit 13 of the watering equipment 8 is also a computer having a CPU, a ROM, and a RAM, and receives fire information (fire point position information and fire source heat generation rate information) from the information processing unit 5 of the fire monitoring system 1. And based on this received fire information, control which opens the control valve 10 of the specific watering head 9 among the watering heads 9 is performed.

  For example, depending on the fire spreading direction and the scale of the fire, the watering head 9 located in the fire spreading direction is selected and its control valve 10 is opened early, or the watering head 9 is selected so as to surround the fire point and controlled. Control to open the valve 10 is performed. In addition, when the fire expansion is faster than expected, control is performed to select the watering head 9 so as to surround the fire points in multiple layers and to open the control valve 10. By performing such control according to the fire situation, it is possible to reliably prevent the spread of fire.

In the present embodiment, the information processing unit 5 calculates the fire point position and fire source heat generation rate information using the following experimental formula (1). Note that a temperature sensor is used as the sensor 4.
^{_{ΔT (r) = 5.38Q f 2/3}} / H c r 2/3 ( provided that, 0.18 <r / H) ...... (1)
ΔT _(r) : Hot air flow rising temperature (K) at a position r away from the center axis of the fire source
Q _f : fire source heat generation rate) (kW)
H _c : Ceiling height (m)
r: Distance from fire source center axis (m)
That is, the gas generated by the combustion of the combustible material (fire source) generates buoyancy due to the high temperature and becomes an updraft. When this updraft collides with the ceiling, it becomes a hot airflow that spreads concentrically along the ceiling. The temperature of the hot airflow after colliding with the ceiling attenuates as the distance r from the center axis of the fire source increases.

  Hereinafter, an example of a method for calculating the fire point position from four temperature sensors (sensors 1 to 4) arranged at random using the above experimental formula (1) will be described with reference to FIGS. . The method for calculating the hot spot position is not limited to this method, and other known methods may be used.

First, as shown in FIG. 2, the position information of the sensor 1 is (x ₁ , y ₁ ), the temperature information is (ΔT ₁ ), the position information of the sensor 2 is (x ₂ , y ₂ ), and the temperature information is (ΔT ₂ ), position information of the sensor 3 is (x ₃ , y ₃ ), temperature information is (ΔT ₃ ), position information of the sensor 4 is (x ₄ , y ₄ ), and temperature information is (ΔT ₄ ).

Next, based on FIG. 3, calculation calculation of the hot spot position is started.
First, in step 1, the information processing section 5 acquires temperature information (ΔT ₁ ) to (ΔT ₄ ) and position information (x ₁ , y ₁ ) to (x ₄ , y ₄ ) of the sensors 1 to 4.

Next, in step 2, it is assumed that the position information of the fire point position (fire point) is (x _f , y _f ), and in step 3, the distance r from the fire point position (x _f , y _f ) to the sensor 1 ₁ , distance r ₂ from fire point position (x _f , y _f ) to sensor 2, distance r ₃ from fire point position (x _f , y _f ) to sensor ₃ , fire point position (x _f , y _f ) The distance r ₄ from the sensor 4 to the sensor 4 is calculated.

Next, in step 4, the temperature information (ΔT ₁ ) to (ΔT ₄ ) of sensors 1 to ₄ and r ₁ to r ₄ obtained in step 3 are substituted into the following equations (a) to (c), and Σ ₁ , Σ ₂ and Σ ₃ are calculated.
Σ ₁ = X ₁ −ΔT ₂ (a)
(However, X ₁ = (r ₁ / r ₂ ) ^2/3 ΔT ₁ )
Σ ₂ = X ₂ −ΔT ₃ (b)
(However, X ₂ = (r ₁ / r ₃ ) ^2/3 ΔT ₁ )
Σ ₃ = X ₃ −ΔT ₄ (c)
(However, X ₃ = (r ₁ / r ₄ ) ^2/3 ΔT ₁ )

Next, in step 5, with respect to Σ ₁ ~Σ ₃ determined in step _{4 | Σ 1 | + | Σ} 2 | + | Σ 3 | perform calculations, in step 6, and stores the result. In step 7, it is determined whether calculation results have been obtained for all target points in the region surrounded by the sensors 1 to 4. And when calculation is not complete | finished about all the target points, a fire point position is reset and step 3-step 6 are repeated. When calculation results are obtained for all target points, a minimum value (for example, 0) is acquired from the stored data in step 8, and in step 9, the minimum value is obtained as the fire point position. Output as (x _f , y _f ) and finish the calculation.

FIG. 4 shows an example of the simulation result of the method for calculating the hot spot position.
This simulation is performed when the minimum value of | Σ ₁ | + | Σ ₂ | + | Σ ₃ | is 0 in Step 4 in FIG. 3, that is, Σ ₁ = 0, Σ ₂ = 0, and Σ ₃ = 0. Is a plot of the calculation results of. The upper part is a plot of temperature information and position information of the sensors 1 to 4, and the lower part is a calculation result. “0” is a plot of the calculation result of Σ ₁ = 0, “1” is a plot of the calculation result of Σ ₂ = 0, and “2” is a plot of the calculation result of Σ ₃ = 0. . The intersection of the “0” curve (circle), the “1” curve (circle), and the “2” curve (circle) is the fire point position to be obtained.

Next, an example of a method for calculating the heat generation rate information of the fire source will be described.
That is, the heat generation rate of the fire source is calculated from the thermal airflow temperature ΔT _{i at} the temperature sensor installation position, the distance r _i from the fire point to the temperature sensor installation position, and the ceiling height H _c using the above-described equation (1). can do.
That is, from equation (1), the heat source heating rate is
Q _f = ΔT _i ^3/2 H _c ^3/2 r _i /12.5
Therefore, the heat generation rate (kW) can be obtained by substituting each parameter (hot air temperature, distance, ceiling height) into this equation (see FIG. 5).

Next, an example of a method for specifying a fire point position when a plurality of temperature sensors are arranged in a grid will be described.
In this case, as shown in FIG. 6, the plurality of temperature sensors are installed at equal intervals in the x and y directions, the interval in the x direction is D _x , and the interval in the y direction is D _y. Is (x _i , y _i ), and the height of the ceiling is H _c . It is not necessary that D _x = D _y .

First, as illustrated in FIG. 7, in step 1, the information processing unit 5 selects the temperature sensor (x _m , y _n ) having the highest temperature from the plurality of temperature sensors. Here, it is simultaneously determined whether or not each temperature sensor is operating normally.

Next, in step 2, the temperature sensor (x _m−1 , y _n ) and the temperature sensor (x _{m + 1} , y _n ) are compared to select a temperature sensor having a high temperature. For example, a temperature sensor (x _{m + 1} , y _n ) is selected.

Next, in step 3, the temperature sensor (x _m , y _n-1 ) and the temperature sensor (x _m , y _{n + 1} ) are compared to select a temperature sensor with a high temperature. For example, a temperature sensor (x _m , y _{n + 1} ) is selected.

Next, in step 4, the fire area is specified. For example, the fire area includes the temperature sensor (x _m , y _n ), the temperature sensor (x _m , y _{n + 1} ), the temperature sensor (x _{m + 1} , y _n ), the temperature sensor (x _{m + 1} , y) from step 2 and step 3. _{n + 1} ).

Next, in step 5, the temperature information in the temperature sensor (x _m , y _n ), the temperature sensor (x _m , y _{n + 1} ), the temperature sensor (x _{m + 1} , y _n ), the temperature sensor (x _{m + 1} , y _{n + 1} ) and Calculate to identify the fire point from the location information.

As shown in FIG. 8, when a fire occurs, a temperature sensor (x ₁ , y ₁ ), a temperature sensor (x ₂ , y ₁ ), a temperature sensor (x ₁ , y ₂ ), and a temperature sensor (x ₂ , y _2). The temperature of the hot airflow at the position) increases as the fire progresses. The hot air flow temperatures at a certain time are respectively assumed to be ΔT (x ₁ , y ₁ ), ΔT (x ₂ , y ₁ ), ΔT (x ₁ , y ₂ ), and ΔT (x ₂ , y ₂ ). Moreover, the installation intervals of the temperature sensors are D _x and D _y , respectively, in the x direction and the y direction.

Here, the information processing unit 5 assumes that the coordinates of the fire point are (x _f , y _f ), and sets the distances in the x direction and the y direction with respect to the installation positions of the respective temperature sensors as shown in FIG.
That is,
d _x1 = x _f −x ₁ (2)
d _x2 = x ₂ -x _f = D _x -d _x1 (3)
d _y1 = y _f −y ₁ (4)
d _y2 = y ₂ -y _f = D _y -d _y1 (5)
Further, it is assumed that the distances from the fire point (x, y) to each temperature sensor installation position are r ₁₁ , r ₂₁ , r ₁₂ and r ₂₂ , respectively. At this time, r ₁₁ , r ₂₁ , r _12, and r ₂₂ are expressed by using the relationships of the equations (2) to (5),
r ₁₁ ² = d _x1 ² + d _y1 ² (6)
r ₂₁ ² = d _x2 ² + d _y1 ² = D _x ² -2D _x d _x1 + d _x1 ² + d _y1 ²
...... (7)
r ₁₂ ² = d _x1 ² + d _y2 ² = d _x1 ² + D _y ² -2D _y d _y1 + d _y1 ²
...... (8)
r ₂₂ ² = d _x2 ² + d _y2 ² = D _x ² -2D _x d _x1 + d _x1 ² + D _y ² -2D _y d _y1 + d _y1 ²
...... (9)
It is expressed.
On the other hand, the relationship between each temperature and the distance from the fire point to each temperature sensor installation position depends on Equation (1). Therefore, the following relationship holds between r ₂₁ , r ₁₂ and r ₂₂ and r ₁₁ .
r ₂₁ = (ΔT (x ₁ , y ₁ ) / ΔT (x ₂ , y ₁ )) ^3/2 r ₁₁ = α ₂₁ r ₁₁ (10)
r ₁₂ = (ΔT (x ₁ , y ₁ ) / ΔT (x ₁ , y ₂ )) ^3/2 r ₁₁ = α ₁₂ r ₁₁ (11)
r ₂₂ = (ΔT (x ₁ , y ₁ ) / ΔT (x ₂ , y ₂ )) ^3/2 r ₁₁ = α ₂₂ r ₁₁ (12)
From equations (6) and (7),
r ₂₁ ² −r ₁₁ ² = D _x ² −2D _x d _x1 (13)
Furthermore, substituting equation (10) into equation (13) and solving for d _x1 ,
d _x1 = ((1-α ₂₁ ² ) r ₁₁ ² + D _x ² ) / 2D _x (14)
Get. However,
α ₂₁ = (ΔT (x ₁ , y ₁ ) / ΔT (x ₂ , y ₁ )) ^3/2 (15)
Similarly, from Equation (6) and Equation (8),
r ₁₂ ² −r ₁₁ ² = D _y ² −2D _y d _y1 (16)
Substituting equation (11) into equation (16) and solving for d _y1 yields:
d _y1 = ((1-α ₁₂ ² ) r ₁₁ ² + D _y ² ) / 2D _y (17)
However,
α ₁₂ = (ΔT (x ₁ , y ₁ ) / ΔT (x ₁ , y ₂ )) ^3/2 (18)
Here, when formula (14) and formula (17) are substituted into formula (6) and rearranged,
Ar ₁₁ ⁴ -2Br ₁₁ ² + C = 0 (19)
Get. However,
A = (1-α ₂₁ ² ) ² / D _x ² + (1-α ₁₂ ² ) ² / D _y ² , B = α ₂₁ ² + α ₁₂ ² , C = D _x ² + D _y ² (20)
From formula (19) r ₁₁ ² = (B ± (B ² -AC) ^1/2 ) / A (21)
Get. The larger solution means that the fire point is outside the range of the flame area. However, since the flame area is specified in step 4, only the smaller solution needs to be used. That is,
r ₁₁ = ((B− (B ² −AC) ^1/2 ) / A) ^1/2 (22)
Get. Therefore, by substituting the values obtained from Equation (15) and Equation (22) into Equation (14) and substituting the values obtained from Equation (18) and Equation (22) into Equation (17), The fire point can be specified.
In the above case, after specifying the four temperature sensors, as shown in FIG. 2 and FIG. 3, in the region surrounded by the four temperature sensors, the calculation is performed by sequentially changing the fire point position. A point position may be specified.

Note that the formula used in a particular method (1) is 0.18 <since limited to use in the range of r / H _c, of the temperature sensor in the apex of the fire area, a position indicating a maximum temperature It is desirable not to use temperature information. For example, assuming that the temperature ΔT (x ₂ , y ₂ ) at the temperature sensor installation position (x ₂ , y ₂ ) in FIG. 8 indicates the maximum temperature, the remaining three points of temperature information and position information are used. What is necessary is just to identify a fire point according to the above-mentioned procedure.

  In the above description, the control unit 13 is configured to control the opening / closing operation of the control valve 10 of the watering head 9 of the watering equipment 8, but the smoke monitoring equipment is provided on the ceiling surface 3 of the fire monitoring target room 2. The smoke start and stop operation of the smoke exhaust facility may be controlled by the control unit 13, and the opening and closing operation of the fire preventive device such as a fire door installed on the partition wall of the fire monitoring target room 2 is controlled. It may be controlled by the unit 13.

It is the schematic which showed the whole fire monitoring system by this invention. It is explanatory drawing which showed the relationship between a temperature sensor and a fire point. It is the flowchart which showed an example of the calculation method of a fire point position. It is explanatory drawing which showed an example of the simulation result obtained by the calculation method of the fire point position of FIG. It is explanatory drawing of the fire source heat generation rate computed based on the fire spot position information specified by the calculation method of the fire spot position of FIG. It is explanatory drawing which showed the positional information on the temperature sensor arrange | positioned at the grid | lattice form, and the height of the ceiling. It is the flowchart which showed an example of the method of specifying a fire point using the temperature sensor shown in FIG. It is explanatory drawing which showed the relationship between the temperature sensor shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fire monitoring system 2 Fire monitoring object room 3 Ceiling surface 4 Sensor 5 Information processing part 6 Fire monitoring room 7 Information output part 8 Sprinkling equipment 9 Sprinkling head 10 Control valve 11 Piping 12 Water supply tank 13 Control part

Claims (6)

  It is installed on the ceiling surface of the fire monitoring target room, receives the fire information output from each sensor and multiple sensors that detect the temperature or smoke density of the fire monitoring target room and output it as fire information when a fire occurs. A fire monitoring system comprising: an information processing unit that calculates and identifies a fire point position based on the fire information and position information of each sensor stored in advance.   Select any four sensors from the plurality of sensors, based on the fire information output from the selected four sensors, and the position information of the four sensors stored in the information processing unit, The fire monitoring system according to claim 1, wherein a fire point position is calculated and specified.   The information processing unit is based on the fire information output from the sensor, the position information of each sensor stored in advance, the height of the ceiling surface of the fire monitoring target room, and the specified fire spot position information. The fire monitoring system according to claim 1, wherein a fire source heat generation rate is calculated.   The fire spot position information or the fire source heat generation speed information output from the information processing unit is received, and based on the received information, watering equipment, smoke exhausting equipment installed on the ceiling surface of the fire monitoring target room, and The fire monitoring system according to any one of claims 1 to 3, further comprising a control unit that controls the operation of fire prevention equipment installed on a partition wall of the fire monitoring target room.   The watering facility is composed of a plurality of watering heads installed on the ceiling surface of the fire monitoring target room and a control valve for opening and closing each watering head, and the opening and closing operation of each control valve is controlled by the control unit. The fire monitoring system according to claim 4, wherein the system is a fire monitoring system. The control unit is installed in a fire monitoring room disposed at a position remote from the fire monitoring target room, the fire information from the sensor output to the control unit in the fire monitoring room, the position information of the sensor, 2. The remote-monitoring of the identified fire point position information, the fire source heat generation speed information, the operation information of the sprinkling equipment, the operation information of the smoke evacuation equipment, and the operation information of the fire protection equipment is performed. The fire monitoring system according to any one of 5.