JP2018061686A - Fire-extinguishing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire-extinguishing system capable of extinguishing a fire that occurs in a house without requiring prior settings.SOLUTION: When fire heat is detected by a fire heat detection part, a drive control part controls drive means so that an imaging direction is oriented to an alert direction, which is the direction of the fire heat, and a fire determination part determines whether or not the fire heat is a fire based on an image captured by imaging means whose imaging direction is oriented to the alert direction. When it is determined that a fire has occurred, a fire extinguisher is actuated so that a fire-extinguishing agent is jetted.SELECTED DRAWING: Figure 11

Description

  The present invention relates to a fire extinguishing system that detects and extinguishes a fire that has occurred in a house.

  In recent years, with the rapid aging of the population, there is no related person who takes care of the person requiring care for home care or the like, and there are increasing cases where the person requiring care is living alone in the house. When a fire occurs in such a situation, there may be a case where only a care recipient who is incapable of hand and foot or difficult to perform complicated operations cannot perform fire fighting activities. Moreover, even if a person who notices a fire rushes to the scene, the fire may spread during that time. Thus, there has been proposed a fire extinguishing system capable of extinguishing fire (hereinafter referred to as “initial fire extinguishing”) at an initial stage before the generated fire spreads (see, for example, Patent Document 1).

  In the prior art fire extinguishing system shown in Patent Document 1, a plurality of fire extinguishing target areas are set in advance in a house, and a fire extinguishing apparatus including an injection port for injecting a fire extinguishing agent is installed in each fire extinguishing target area. Yes. In addition, a stove or the like placed in the house is stored in advance as an excluded area to be excluded from the fire judgment, and fire is detected if fire is detected outside the excluded area based on an image of the house taken by the camera. It is determined that it has occurred.

  When it is determined that a fire has occurred, an image of the house is transmitted to a registered mobile terminal (such as a smartphone), and when a fire extinguishing command is received from the mobile terminal, a fire extinguishing agent is injected into the designated fire extinguishing target area. The fire is extinguished.

Japanese Patent Application Laid-Open No. 2016-112036

  However, in the fire extinguishing system of the above-mentioned patent document, in order to extinguish a fire, it is necessary to register a fire extinguishing target area in advance, and to adjust the direction of the injection port so that a fire extinguishing agent is sprayed on the fire extinguishing target area. There was a problem that it took time and labor for setting up and the skill for setting up.

  Then, an object of this invention is to provide the fire extinguishing system which can extinguish the fire which generate | occur | produced in the house, without requiring a prior setting.

  A fire extinguishing system according to the present invention is a fire extinguishing system that detects and extinguishes a fire that has occurred in a house, and includes a fire extinguisher that has a jet that jets a fire extinguishing agent into the house, and the direction of the jet is a horizontal rotation direction Driving means for moving in the vertical rotation direction, imaging means whose imaging direction is the same as the direction of the ejection port, the imaging direction moving integrally with the ejection port, and a drive control unit for controlling the driving unit, A fire detection unit that detects a heat based on an image captured by the imaging unit, and a fire determination unit that determines whether or not the fire detected by the fire detection unit is a fire. When the detection unit detects the fire heat, the drive control unit controls the drive unit so that the imaging direction is a warning direction that is the fire heat direction, and the fire determination unit determines the imaging direction. Take the picture in the direction Based on the image captured by the means, it is determined whether or not the fire is a fire. When the fire determination unit determines that a fire has occurred, the fire extinguishing device is injected so that the fire extinguishing agent is injected. Operate.

  ADVANTAGE OF THE INVENTION According to this invention, the fire which generate | occur | produced in the house can be extinguished without requiring a prior setting.

The perspective view of the room in which the fire extinguishing system of one embodiment of this invention is installed The perspective view of the fire extinguishing apparatus with which the fire extinguishing system of one embodiment of this invention is provided Structure explanatory drawing of the fire extinguishing apparatus with which the fire extinguishing system of one embodiment of this invention is provided The block diagram which shows the control system of the fire extinguishing system of one embodiment of this invention Explanatory drawing which shows an example of the monitoring area | region set in the room which the fire extinguishing system of one embodiment of this invention monitors Explanatory drawing which shows an example of the fire heat detected by the fire extinguishing system of one embodiment of this invention in the monitoring area | region Explanatory drawing which shows an example of the alert area set by the fire extinguishing system of one embodiment of this invention (A) (b) (c) Explanatory drawing of calculation of the heat-heat ratio in the fire extinguishing system of one embodiment of this invention (A) (b) (c) Explanatory drawing which shows the example of the reference | standard figure extracted in the fire extinguishing system of one embodiment of this invention (A) (b) (c) Explanatory drawing of the fire determination in the fire extinguishing system of one embodiment of this invention Explanatory drawing of the injection method of the fire extinguisher in the fire extinguishing system of one embodiment of this invention (A) (b) Explanatory drawing of the injection method of the fire extinguisher in the fire extinguishing system of one embodiment of this invention The flowchart explaining the fire extinguishing method by the fire extinguishing system of one embodiment of this invention The flowchart explaining the warning information storage process by the fire extinguishing system of one embodiment of this invention The flowchart explaining the fire determination process by the fire extinguishing system of one embodiment of this invention

  FIG. 1 shows an example of a house room 2 in which a fire extinguishing system 1 according to an embodiment of the present invention is installed. The fire extinguishing system 1 has a function of detecting and extinguishing a fire that has occurred in the house (inside the room 2). The room 2 is surrounded by walls 2A, 2B, 2C, 2D. In the room 2, a telephone 4 with a fax machine, a TV 6, a stove 7, a Buddhist altar 8 and the like are installed in addition to a bed 4 for a care recipient 3 to rest. The power cords of electrical appliances such as a telephone 5 with a fax machine and a television 6 are connected to a power strip (not shown). The combustion cylinder 7a of the stove 7, the candle 8a provided to the Buddhist altar 8, the power tap, and the like can be a source of fire.

  Next, the configuration of the fire extinguishing system 1 will be described with reference to FIGS. 2 and 3. The fire extinguishing system 1 includes a fire extinguishing device 10 and a control device 31. The fire extinguishing apparatus 10 is attached using a band 13 to a bracket 12 whose main body 11 is fixed to the wall 2B. A siphon tube 14 is disposed inside the main body 11 and a fire extinguishing agent 15 is sealed under pressure. The upper end of the siphon tube 14 is connected to the electromagnetic valve 16 outside the main body 11. The solenoid valve 16 is controlled to be opened and closed by a fire extinguishing control unit 39 (see FIG. 4) provided in the control device 31, and is kept closed except during fire extinguishing.

  A base portion 17 fixed to the main body portion 11 is disposed on the upper portion of the main body portion 11. The base portion 17 may be fixedly disposed on the bracket 12. The control device 31 is disposed inside the base portion 17. A horizontal turntable 18 is disposed above the base portion 17. The horizontal turntable 18 drives the horizontal rotation motor 18a (see FIG. 4) to rotate the rotation axis 18b in the Z direction (vertical direction) perpendicular to the horizontal plane in the horizontal rotation direction θxy with respect to the base 17 as the rotation center. Rotate.

  On the upper surface of the horizontal turntable 18, a pair of rotating body support portions 19 are erected. A rotating body 20 is disposed between the pair of rotating body support portions 19. The rotator 20 drives the vertical rotation motor 20a (see FIG. 4) to move the rotator 20 up and down with respect to the pair of rotator support portions 19 with the horizontal rotation shaft 20b passing between the pair of rotator support portions 19 as a rotation center. It rotates in the rotation direction θz. The horizontal rotation motor 18a and the vertical rotation motor 20a are driven and controlled by a drive control unit 32 (see FIG. 4) included in the control device 31.

  In FIG. 3, the rotating body 20 is provided with a nozzle 22 having an injection port 21 that opens to the outer peripheral surface of the rotating body 20. The nozzle 22 is connected to the electromagnetic valve 16 via a universal joint 23 and a connecting pipe 24. When the solenoid valve 16 is opened (becomes an open state) by the fire extinguishing control unit 39, the extinguishing agent 15 pressurized and sealed in the main body 11 of the fire extinguishing apparatus 10 is added to the siphon tube 14, the solenoid valve 16, the connecting tube 24, Injected from the injection port 21 through the universal joint 23 and the nozzle 22 toward the injection direction 21a (the direction of the injection port 21).

  Thus, the fire extinguishing apparatus 10 has the injection port 21 which injects the fire extinguisher 15 into the house (inside the room 2). The horizontal rotation motor 18a and the vertical rotation motor 20a constitute drive means 25 (see FIG. 4) that moves the ejection direction 21a (the direction of the ejection port 21) in the horizontal rotation direction θxy and the vertical rotation direction θz. Then, the drive control unit 32 controls the drive of the drive unit 25. In addition, you may make it connect between the nozzle 22 and the solenoid valve 16 using a flexible flexible pipe | tube instead of the universal joint 23 and the connecting pipe 24. FIG.

  In FIG. 3, an imaging port 26 is opened on the outer peripheral surface of the rotating body 20. The rotator 20 is provided with a visible light camera 27 so that the optical axis 27 a penetrates the imaging port 26. The visible light camera 27 captures a visible light image in the house (in the room 2) through the imaging port 26 with the optical axis 27a as the center of imaging. The visible light camera 27 is disposed above the nozzle 22 so that the optical axis 27a is in the same direction as the ejection direction 21a.

  The rotating body 20 is provided with a filter insertion / extraction means 29 (see FIG. 4) for inserting and removing the infrared transmission filter 28 between the visible light camera 27 and the imaging port 26 (arrow a). The infrared transmission filter 28 is a filter that selectively transmits infrared rays contained in visible light. By imaging with the visible light camera 27 through the infrared transmission filter 28, an infrared image can be obtained with the visible light camera 27.

  The filter insertion / extraction means 29 may be configured so that the infrared transmission filter 28 can be taken in and out in front of the visible light camera 27. For example, the infrared transmission filter 28 may be swingably moved by a rotary motor (not shown), or the infrared transmission filter 28 may be reciprocated by a direct acting motor (not shown). The insertion / extraction (insertion / extraction) of the infrared transmission filter 28 by the filter insertion / extraction means 29 is controlled by the imaging control unit 33 (see FIG. 4) provided in the control device 31.

  Thus, the visible light camera 27 and the filter insertion / extraction means 29 for inserting / removing the infrared transmission filter 28 in front of the visible light camera 27 constitute an imaging means 30 (see FIG. 4) for imaging the house (inside the room 2). To do. With this configuration, the visual field image and the infrared image captured by the imaging unit 30 have the same visual field without using any special alignment unit. The imaging means 30 has the same optical axis 27a (imaging direction) as the ejection direction 21a (direction of the ejection port 21), and the optical axis 27a (imaging direction) moves integrally with the ejection port 21. With this configuration, the direction of the ejection port 21 can be adjusted to the fire extinguishing target by directing the imaging direction to the fire direction (matching the fire extinguishing target to the center of the image).

  Next, a control system of the fire extinguishing system 1 will be described with reference to FIG. The fire extinguishing system 1 includes a control device 31, a fire extinguishing device 10, a driving unit 25, and an imaging unit 30. The control device 31 includes a drive control unit 32, an imaging control unit 33, a monitoring control unit 34, a fire heat detection unit 35, a reference graphic extraction unit 36, a fire heat rate calculation unit 37, a fire determination unit 38, a fire extinguishing control unit 39, and a monitoring information storage. Unit 40, initial heat storage unit 41, and warning information storage unit 42.

  The drive control unit 32 controls the horizontal rotation motor 18a and the vertical rotation motor 20a included in the drive unit 25 to drive the direction of the injection port 21 (the injection direction 21a) and the horizontal rotation direction θxy specified by the monitoring control unit 34. Move so as to face the vertical rotation direction θz. The imaging control unit 33 controls the visible light camera 27 and the filter insertion / extraction unit 29 included in the imaging unit 30 to capture a visible light image and an infrared image.

  Specifically, when a visible light image is captured, the imaging control unit 33 causes the visible light camera 27 to capture an image without inserting the infrared transmission filter 28 in front of the visible light camera 27. When capturing an infrared image, the imaging control unit 33 causes the visible light camera 27 to capture an image with the infrared transmission filter 28 inserted in front of the visible light camera 27. That is, the visible light camera 27 with the infrared transmission filter 28 inserted in front becomes infrared imaging means for imaging an infrared image, and the visible light camera 27 without the infrared transmission filter 28 inserted in front has visible light imaging means for imaging a visible light image. It becomes.

  Thus, the imaging means 30 has an infrared imaging means and a visible light imaging means. Note that the image pickup means 30 is not limited to the above-described configuration. For example, an image incident from a common optical axis is divided into two by a half mirror and the like, and each is incident on an infrared camera and a visible light camera to receive infrared rays. An image and a visible light image may be captured.

  In FIG. 4, the monitoring control unit 34 controls the driving means 25 via the drive control unit 32 and stores a plurality of monitoring directions (directions of the optical axis 27 a of the visible light camera 27) stored in the monitoring information storage unit 40. Based on the above, a monitoring process for imaging the house (inside the room 2) is executed while sequentially moving the imaging direction of the imaging means 30 (the direction of the optical axis 27a of the visible light camera 27). That is, in the monitoring process, the drive control unit 32 drives and controls the driving unit 25 so that the imaging direction sequentially faces a plurality of preset monitoring directions. Then, the monitoring control unit 34 controls the imaging unit 30 via the imaging control unit 33 to capture an infrared image in the monitoring direction.

  The plurality of monitoring directions are set in consideration of the viewing angle of the visible light camera 27 and the position of the imaging means 30 of the fire extinguishing system 1 installed in the house. That is, in setting the monitoring direction, it is not necessary to consider the layout of the house (such as the position of furniture in the room 2), and after installing the fire extinguishing system 1, the position of the furniture in the room 2 is changed. There is no need to reset (change) the monitoring direction.

  Here, the monitoring direction in the monitoring process will be described with reference to FIG. In the example of FIG. 5, the entire visual field 50 seen from the position of the imaging means 30 of the fire extinguishing system 1 installed in the room 2 is divided into three in the horizontal direction and two in the vertical direction. The monitoring direction is set by defining the area A2, the monitoring area A3, and the monitoring area B1, the monitoring area B2, and the monitoring area B3 from the lower left. That is, the direction in which the optical axis 27a of the visible light camera 27 faces the center of each of the monitoring areas A1 to A3 and B1 to B3 is stored in the monitoring information storage unit 40 as a monitoring direction.

  In the monitoring process, the monitoring control unit 34, for example, 10 seconds in the order of monitoring area A1, monitoring area A2, monitoring area A3, monitoring area B3, monitoring area B2, monitoring area B1, monitoring area A1, monitoring area A2, and so on. The imaging direction of the imaging means 30 is moved at intervals, and infrared images of the monitoring areas A1 to A3 and B1 to B3 are captured. That is, an infrared image is captured each time the imaging direction is in one monitoring direction. As a result, the latest infrared image of the entire visual field 50 is captured in 60 seconds.

  In FIG. 4, the fire detection unit 35 performs image processing on the infrared image captured by the imaging unit 30, extracts a region (high temperature region) higher than a predetermined temperature, and detects it as fire heat. Execute. More specifically, in the monitoring process, the fire detection unit 35 detects the presence or absence of fire heat based on the infrared images of the monitoring regions A1 to A3 and B1 to B3. That is, the fire detection unit 35 extracts the heat as a fire image from the infrared image (image) captured by the infrared image capturing unit (the image capturing unit 30).

  As described above, the thermal detection unit 35 is an infrared imaged in a state where the imaging unit 30 has inserted the infrared transmission filter 28 in front of the visible light camera 27 every time the imaging direction (optical axis 27 a) faces one monitoring direction. Based on the image, the heat is detected or it is determined whether there is any heat. Further, an infrared imaging means (imaging means 30) and a fire detection unit 35 that detects the fire heat H from the infrared image picked up by the infrared image pickup means determine whether or not the fire heat H is present in the house (in the room 2). The fire heat monitoring means to monitor is comprised.

  Here, an example of the thermal image 51 extracted by the thermal detection unit 35 in the thermal detection process will be described with reference to FIG. FIG. 6 shows the heat H1 extracted by the heat detection unit 35 based on the infrared image obtained by imaging the monitoring region B2. This fire heat H1 is obtained by imaging the combustion cylinder 7a, which has become high temperature in the burning stove 7, with infrared rays.

  In FIG. 4, when the fire heat H1 is detected by the fire heat detector 35, the monitoring controller 34 calculates the direction in which the optical axis 27a of the visible light camera 27 faces the center of the fire heat H1, and the fire heat H1 is detected. The direction calculated in association with the area B1 is stored in the alert information storage unit 42 as the alert direction. When the warning direction is stored, the monitoring control unit 34 controls the driving means 25 via the drive control unit 32 so that the warning direction also faces in addition to the monitoring direction. That is, when the fire heat detection unit 35 detects the fire heat H1, the drive control unit 32 controls the drive means 25 so that the warning direction in which the imaging direction is the direction of the fire heat H1 is sequentially directed in addition to the plurality of monitoring directions.

  Here, the warning direction will be described with reference to FIG. When the fire heat H1 is detected in the monitoring region B2 (see FIG. 6), the direction in which the image pickup direction of the image pickup means 30 faces the center of the fire heat H1 (combustion cylinder 7a of the stove 7) is set as a warning direction. In FIG. 7, the image range captured by the visible light camera 27 in a state where the imaging direction of the imaging unit 30 is directed to the warning direction is displayed as a warning area C1 over the entire visual field 52. That is, the warning area C1 is set so that the combustion cylinder 7a of the stove 7 is at the center.

  When the warning area C1 is added (stored), in the monitoring process, the monitoring control unit 34, for example, the monitoring area B1, the warning area C1, the monitoring area A1, the warning area C1, the monitoring area A2, the warning area C1, and the monitoring area A3. By moving the imaging direction of the imaging means 30 in the order of the warning area C1, the monitoring area B3, the warning area C1, the monitoring area B2, the warning area C1, and so on, the monitoring areas A1 to A3, B1 to B3, and the warning area The image of C1 is taken.

  That is, while each of the monitoring areas A1 to A3 and B1 to B3 is imaged, the warning area C1 is imaged at least once, and a fire determination process described later is executed. For example, when the imaging direction is moved at intervals of 10 seconds toward the next monitoring areas A1 to A3 and B1 to B3, the warning area C1 is set at least once (a plurality of warning directions are set during the 10 seconds). If so, all alert directions are imaged. The monitoring control unit 34 causes both an infrared image and a visible light image to be captured in capturing the alert area C1.

  In FIG. 4, a reference graphic extraction unit 36 is a graphic associated with an image of fire heat H (hereinafter referred to as “fire heat image”) by subjecting the visible light image and the infrared image captured by the image capturing means 30 to image processing. A reference graphic extraction process for extracting the reference graphic is executed. That is, the reference graphic extraction unit 36 extracts a reference graphic that is a graphic associated with the thermal image based on the graphic included in the image (visible light image, infrared image) captured by the imaging unit 30.

  More specifically, the reference graphic extraction unit 36 includes at least a graphic that surrounds the fire heat H in the thermal image among the graphics included in the visible light image (image) captured by the imaging unit 30, or around the fire heat H. A reference graphic is extracted including the outline of any graphic. That is, the reference graphic extraction unit 36 extracts the reference graphic from the visible light image captured by the visible light imaging unit (imaging unit 30).

  Here, an example of the reference graphic will be described with reference to FIG. FIG. 8A shows a visible light image 53 of the alert area C1 set after the combustion cylinder 7a of the stove 7 is detected as the fire heat H1. FIG. 8B shows a reference graphic F1 (first example) extracted by the reference graphic extraction unit 36 based on the visible light image 53 shown in FIG. In this example, the contour of the reflector around the combustion cylinder 7a of the stove 7 is extracted as a reference graphic F1 surrounding the heat H1 among the figures included in the visible light image 53. In FIG. 8C, the heat H1 of the heat image is superimposed on the extracted reference graphic F1 and displayed. In this example, among the figures included in the visible light image 53, one figure surrounding one fire heat H1 is extracted as the reference figure F1.

  Next, another example of the basic figure will be described with reference to FIG. FIG. 9A shows a visible light image 56 of the alert area C2 set after the flames 8b lit on the two candles 8a provided to the Buddhist altar 8 are detected as the fire heat H2a and the fire heat H2b, respectively. Yes. In FIG. 9B, the thermal image H2a and the thermal image H2b of the thermal image are superimposed on the reference graphic F2 (second example) extracted by the reference graphic extraction unit 36 based on the visible light image 56 shown in FIG. 9A. Is displayed. In this example, among the figures included in the visible light image 56, one figure that surrounds the two heats H2a and H2b is extracted as the reference figure F2.

  9C shows a reference graphic F3a and a reference graphic F3b (second example) extracted by the reference graphic extraction unit 36 based on the visible light image 56 shown in FIG. The heat H2b is superimposed and displayed. In this example, the outlines of the candle 8a in the vicinity (downward) of the two heats H2a and H2b among the figures included in the visible light image 56 are extracted as the reference figure F3a and the reference figure F3b, respectively. In other words, two reference figures F3a and F3b corresponding to the fire heat H2a and the fire heat H2b are extracted in association with the fire image.

  In FIG. 4, the heat / heat ratio calculation unit 37 calculates the ratio of the area of the heat H in the heat / heat image to the area of the reference graphic F extracted by the reference graphic extraction unit 36 as the heat / heat ratio.

  Here, with reference to FIG.8 (c), the example of a heat-heat ratio is demonstrated. In FIG. 8C, the heat H1 of the heat image (see also FIG. 6) is displayed superimposed on the reference figure F1 shown in FIG. 8B. The heat-heat ratio calculation part 37 calculates the ratio of the area of the heat H1 with respect to the area of the reference | standard figure F1 as a heat-heat ratio.

  In FIG. 4, the initial heat storage unit 41 stores initial heat information including an initial heat image, an initial reference graphic, and an initial heat ratio. The initial fire image is an image of the fire H extracted from the infrared image captured by the infrared imaging means (imaging means 30) in which the fire heat H is detected in the monitoring process and the imaging direction is directed to the monitoring direction. The initial reference graphic is a reference graphic F associated with the fire heat H of the initial fire image. The initial heat ratio is the ratio of the heat H in the initial heat image relative to the area of the initial reference graphic.

  In FIG. 4, the fire determination unit 38 determines the occurrence of a fire based on the ratio of heat to heat. More specifically, the fire determination unit 38 includes the current infrared image and visible light image (warning image) of the warning area C1 (C2) imaged in the monitoring process, and the initial heat stored in the initial fire storage unit 41. A fire determination process for determining whether or not the fire heat H is a fire is executed based on the fire image, the initial reference figure, and the initial heat and heat ratio. That is, the fire determination unit 38 detects the fire heat H detected by the fire heat detection unit 35 based on the infrared image and the visible light image captured by the image capturing unit 30 with the image capturing direction (the direction of the optical axis 27a) in the alert direction. Determine if there is a fire. In addition, the imaging unit 30, the fire heat detection unit 35, and the fire determination unit 38 constitute a fire detection unit that detects a fire that has occurred indoors (in the room 2).

  Here, with reference to FIG. 10, the fire determination process by the fire determination part 38 is demonstrated more concretely. 10 (a) to 10 (c), the reference extracted from the infrared image and the visible light image (warning image) of the current warning area C1 after a certain amount of time has elapsed since the first detection of the heat H1. The figure F and the fire heat H of the fire image are displayed in an overlapping manner.

  In the example of FIG. 10A, the reference graphic F1 (1) matches the reference graphic F1 (initial reference graphic) of FIG. 8C. In this case, in the fire determination unit 38, the fire heat rate calculated by the fire heat rate calculation unit 37 from the reference figure F1 (1) and the fire heat H1 (1) of the heat image is increased to a predetermined rate or more from the initial fire heat rate. It is determined that a fire has occurred. That is, the fire determination unit 38 calculates the fire heat ratio in the current image of the warning area C1 (warning image) when the fire heat H1 is first detected by the fire monitoring means (infrared imaging means, fire heat detection unit 35). It is determined that a fire has occurred when the initial heat rate, which is the ratio of the heat, has increased to a predetermined rate or more.

  In the example of FIG. 10B, the reference figure F1 (2) is larger than the reference figure F1 (initial reference figure) in FIG. Further, the fire heat H1 (2) of the fire image is larger than the fire heat H1 (fire heat H1 of the initial fire image) of FIG. However, the reference figure F1 (2) in FIG. 10 (b) and the fire heat H1 (2) in the fire image are similar to the reference figure F1 (initial reference figure) and the fire heat H1 in the initial heat image in FIG. 8 (c). Are in a relationship. That is, the fire-heat ratio calculated from FIG. 10B is the same as the initial heat-heat ratio calculated from FIG. In this case, the fire determination unit 38 determines that the stove 7 has been moved to a position approaching the imaging means 30 of the fire extinguishing system 1, but no fire has occurred.

  In the example of FIG. 10C, the reference figure F1 (3) has the same shape as the reference figure F1 (initial reference figure) in FIG. 8C, but the positions do not match. Moreover, although the shape of the heat H1 (3) of the heat image is the same as that of the heat H1 (fire heat H1 of the initial heat image) in FIG. 8C, the positions do not match. However, the relative relationship of the heat H1 (3) of the fire image with respect to the reference graphic F1 (3) and the relative relationship of the fire heat H1 of the initial fire image with respect to the reference graphic F1 (initial reference graphic) are the same. And the fire-heat ratio calculated from FIG.10 (c) is the same as the initial heat-heat ratio calculated from FIG.8 (c). In this case, the fire determination unit 38 determines that the stove 7 has been moved in the lateral direction with respect to the imaging means 30 of the fire extinguishing system 1, but no fire has occurred.

  In this way, the fire determination unit 38 extracts the reference graphic F extracted from the current warning area C1 image (warning image) when the initial reference graphic (fire heat H is first detected by the heat monitoring means). The relative relationship between the fire heat H and the reference graphic F in the fire image is the same as the relative relationship between the fire heat H and the initial reference graphic in the initial fire image (the fire heat H is the first by the fire monitoring means). If the fire rate is higher than the initial rate, the fire is judged to have occurred.

  As described above, in the fire extinguishing system 1, the fire monitoring means, the imaging means 30, the fire heat detection unit 35, the reference graphic extraction unit 36, the fire heat rate calculation unit 37, and the fire determination unit 38 are in the house (in the room 2). A fire determination system is configured to determine whether or not a fire has occurred. In the fire determination system, the fire determination unit 38 determines that a fire has occurred when the ratio of heat to heat is higher than the initial ratio of heat to a predetermined ratio. Accordingly, it is possible to determine whether or not a fire has occurred in the house (in the room 2) without requiring prior settings.

  In FIG. 4, when the fire determination unit 38 determines that a fire has occurred, the fire extinguishing control unit 39 performs a fire extinguishing process that activates the fire extinguishing device 10 (opens the electromagnetic valve 16) so that the fire extinguishing agent 15 is injected. Let it run. In the fire extinguishing process, the fire extinguishing control unit 39, when the fire determination unit 38 (fire detecting means) detects a fire, the direction of the injection port 21 facing the detected fire direction is vertically changed within a predetermined range by the driving means 25. The fire extinguishing agent 15 is injected from the injection port 21 while being controlled by the drive control unit 32 so as to move. Thus, by spraying the fire extinguishing agent 15 while moving the injection port 21 in the vertical direction, it is possible to expand the spray destination of the fire extinguishing agent 15 and reliably extinguish the fire generated in the house (in the room 2). .

  Here, with reference to FIG. 11, FIG. 12, the fire extinguishing process which injects the fire extinguishing agent 15 while moving the injection nozzle 21 is demonstrated. In FIG. 11, as shown in FIG. 10A, since the fire heat H <b> 1 (1) in the alert area C <b> 1 is determined to be a fire by the fire determination unit 38, the injection port 21 of the fire extinguishing system 1 is moved vertically (arrow b). The state where the extinguishing agent 15 is being injected near the combustion cylinder 7a of the fire source stove 7 while moving is shown from the side. FIG. 12A shows a state in which FIG. 11 is viewed from the position of the imaging means 30 of the fire extinguishing system 1.

  In FIG. 11, when the imaging means 30 is imaging the alert area C1, the ejection port 21 faces the ejection direction 21a (0) (the ejection direction 21a at the time of imaging). If the fire determination unit 38 determines that a fire has occurred from this state, the driving unit 25 sprays the extinguishing agent 21 in the jetting direction 21a below the jetting direction 21a (0) at the time of imaging. It moves up and down in an injection range R1 (predetermined range) between (B) and the upper injection direction 21a (U) for spraying the extinguishing agent 15 above the injection direction 21a (0) at the time of imaging. As a result, the fire extinguishing agent 15 is sprayed over a region including a plurality of spraying ranges 64 shown in FIG.

  As described above, the drive control unit 32 controls the drive unit 25 so that the injection range R1 (predetermined range) includes at least the lower side of the fire heat H detected by the fire heat detection unit 35. The source of the fire is often at the lower end of the heat H detected from the infrared image or below the heat H, and when the room 2 is full of smoke, the position of the fire H is correctly detected It may not be done. Even in such a case, the fire extinguishing agent 15 is injected while moving the injection port 21 in the vertical direction so that the injection range R1 includes the lower part of the heat H detected by the heat detection unit 35. The fire that occurred in (1) can be extinguished reliably.

  FIG. 12B shows another embodiment in which the injection direction 21 a of the injection port 21 is moved when the extinguishing agent 15 is being injected. In this example, in the fire extinguishing process, the fire extinguishing control unit 39 draws a trajectory of the character “8” (∞) in which the injection direction 21a (R) is laid down about the injection direction 21a (0) at the time of imaging. In addition, the drive unit 25 is controlled via the drive control unit 32. That is, when the extinguishing agent 15 is injected from the injection port 21, the drive control unit 32 moves the injection direction 21a (the direction of the injection port 21) vertically within a predetermined range (injection range R1). The drive unit 25 is controlled so that the injection direction 21a (the direction of the injection port 21) is also moved in the horizontal direction within a predetermined range (injection range R2).

  Thereby, even if the room 2 is filled with smoke and the position of the heat H cannot be accurately detected, it is possible to surely extinguish the fire generated in the house (in the room 2). Note that the trajectory of the injection direction 21a (R) is not limited to the “8” character laid sideways, and may be any as long as the injection port 21 moves in the horizontal direction in addition to the vertical direction.

  As described above, the fire extinguishing system 1 according to the present embodiment includes the fire extinguishing apparatus 10 having the ejection port 21 that ejects the fire extinguishing agent 15 into the house (in the room 2), and the direction of the ejection port 21 (the ejection direction 21a). ) In the horizontal and vertical directions, a drive control unit 32 that controls the drive unit 25, and a fire detection unit that detects a fire that has occurred in the house.

  When the fire detection means detects a fire, the fire extinguishing system 1 is driven so that the direction of the injection port 21 facing the detected fire direction moves up and down within a predetermined range (injection range R1) by the drive means 25. While being controlled by the control unit 32, the fire extinguishing agent 15 is jetted from the jet port 21 to extinguish the fire generated in the house. Thereby, it is possible to surely extinguish a fire generated in the house. The fire detection means may be any means that can detect a fire that has occurred in the house. For example, the fire detection means may detect the fire by measuring the temperature of the heat generated in the house by a temperature sensor.

  Further, the fire extinguishing system 1 of the present embodiment has the fire extinguishing apparatus 10, the driving unit 25, and the imaging direction (optical axis 27 a) that is the same as the direction of the ejection port 21, and the imaging direction is integrated with the ejection port 21. Based on the moving image pickup means 30, the drive control section 32, and the image picked up by the image pickup means 30, a heat detection section 35 for detecting the heat H, and whether the heat H detected by the heat detection section 35 is a fire. A fire determination unit 38 for determining whether or not.

  Then, when the heat detection unit 35 detects the heat H, the drive control unit 32 controls the drive means 25 so that the image capturing direction is in a warning direction that is the direction of the heat H, and the fire determination unit 38 determines the image capturing direction. Based on the image picked up by the image pickup means 30 directed in the warning direction, it is determined whether or not the fire heat H is a fire, and when the fire determination unit 38 determines that a fire has occurred, the fire extinguishing agent 15 is injected. The fire extinguishing device 10 is operated to extinguish a fire generated in the house. Thereby, after installing the fire extinguishing system 1 in a house, the fire which generate | occur | produced in the house can be extinguished, without requiring special setting (advance setting).

  Next, with reference to FIGS. 13 to 15, a fire extinguishing method for determining that a fire has occurred in the house by the fire extinguishing system 1 and extinguishing the fire will be described. In FIG. 13, first, the imaging direction of the imaging unit 30 is set to one monitoring direction among a plurality of monitoring directions set in advance by the monitoring control unit 34 controlling the driving unit 25 via the drive control unit 32. It is assumed that it is directed (for example, monitoring area B2 in FIG. 5). In this state, the supervisory control unit 34 controls the imaging unit 30 via the imaging control unit 33 to capture an infrared image with the infrared transmission filter 28 inserted in front of the visible light camera 27 by the filter insertion / extraction unit 29. (ST1: Monitoring area imaging process). That is, the imaging unit 30 images the interior of the house (inside the room 2).

  Next, the fire detection unit 35 determines whether there is fire H based on the captured infrared image (ST2: fire detection detection step). That is, in the monitoring area imaging step (ST1) and the thermal detection determination step (ST2), the infrared imaging means (imaging means 30) takes an infrared image inside the house (in the room 2), and the thermal detection unit 35 detects the infrared image. By detecting whether or not there is fire heat H, the fire heat monitoring means (infrared imaging means, fire heat detection unit 35) is a fire heat monitoring process for monitoring whether there is fire heat H in the house.

  When the fire heat H is detected (Yes in ST2), the monitoring controller 34 determines whether or not the fire heat H has been detected in the monitoring region (ST3). That is, it is determined whether or not the initial heat information relating to the monitoring area is stored in the initial heat storage unit 41. When the fire heat H has not been detected in the monitoring area, that is, when the initial fire heat information is not stored (No in ST3), the initial heat storage process is executed (ST4: initial fire heat storage process). If fire H has been detected in the monitoring area, that is, if initial fire heat information is stored (Yes in ST3), a fire determination process is executed (ST5: fire determination process step). .

  Here, with reference to FIG. 14, the flow of the initial thermal storage process (initial thermal storage process (ST4)) will be described. First, the monitoring control unit 34 controls the driving unit 25 via the drive control unit 32 to set the imaging direction of the imaging unit 30 (the optical axis 27a of the visible light camera 27) to the heat so that the fire H becomes the center of the image. Turn to the center of H (ST11). Next, the monitoring control unit 34 stores the imaging direction of the imaging unit 30 at this time in the warning information storage unit 42 as a warning direction (ST12). Note that the imaging field of view of the imaging means 30 with the imaging direction in the warning direction is a warning area (for example, the warning area C1 in FIG. 7).

  Next, the monitoring control unit 34 controls the imaging unit 30 via the imaging control unit 33 to capture an infrared image and a visible light image (ST13) (ST13: initial image imaging process). That is, when the fire heat H is detected in the fire heat monitoring process (Yes in ST2), in the initial image capturing process (ST13), the image pickup means 30 displays an initial image (initial infrared image, initial visible image) in the house (in the room 2). An optical image).

  Next, the fire detection unit 35 extracts the heat H from the initial infrared image and stores it as the initial heat image in the initial heat storage unit 41 (ST14: initial heat extraction step). That is, in the initial fire extraction process (ST14), the heat H is extracted as an initial fire image from the initial infrared image (initial image). Next, the reference graphic extraction unit 36, based on the initial visible light image (for example, the visible light image 53 in FIG. 8A), the reference graphic F associated with the initial thermal image (for example, the reference in FIG. 8B). The graphic F1) is extracted and stored in the initial heat storage unit 41 as an initial reference graphic (ST15: initial reference graphic extraction step). That is, in the initial reference graphic extraction step (ST15), an initial reference graphic that is a graphic associated with the initial thermal image is extracted based on the graphic included in the initial visible light image (initial image).

  Next, the heat-heat ratio calculating unit 37 calculates the ratio of the area of the fire heat H in the initial heat-heat image to the area of the initial reference figure as the initial heat-heat ratio and stores it in the initial heat-heat storage unit 41 (ST16: initial heat-heat ratio calculating step). That is, in the initial fire rate calculation step (ST16), the ratio of the area of the fire heat H in the initial fire image relative to the area of the extracted initial reference figure is calculated as the initial fire rate. When the initial heat information such as the initial heat image, the initial reference graphic, the initial heat ratio, and the warning direction are stored, the series of initial heat storage processing ends.

  Next, with reference to FIG. 15, the flow of the fire determination process (fire determination process step (ST5)) will be described. First, the monitoring control unit 34 controls the driving unit 25 via the drive control unit 32 to change the imaging direction of the imaging unit 30 to the warning direction stored in the warning information storage unit 42 (ST21). Thereby, the direction of the injection port 21 (injection direction 21a) faces the direction of the heat H in the alert area.

  Next, the monitoring control unit 34 controls the imaging means 30 via the imaging control unit 33 to capture a visible light image and an infrared image (hereinafter referred to as “warning image”) of the current warning area (ST22: warning image shooting). Process). That is, after the initial heat ratio is calculated in the initial heat storage process (ST4) (Yes in ST3), the imaging means 30 captures the house (inside the room 2) as a warning image in the warning image imaging process (ST22). .

  Next, the fire detection unit 35 extracts the heat H from the infrared image included in the warning image as a warning fire image (ST23: warning fire extraction step). Thus, in the initial fire extraction step (ST14) and the warning fire extraction step (ST23), the initial fire image and the warning fire image are extracted from the infrared image captured by the infrared imaging means (imaging means 30).

  Next, the fire determination unit 38 determines whether or not there is a fire H in the warning fire image, that is, whether or not the fire H has disappeared (ST24). When the heat H is extinguished (Yes in ST24), the heat detection unit 35 is stored in the initial heat information stored in the initial heat storage unit 41 and the warning information storage unit 42 regarding the heat H. The warning direction is cleared (ST25), and the fire determination process is completed.

  When the heat H has not disappeared (No in ST24), the reference graphic extraction unit 36 extracts a reference graphic F that is a graphic associated with the warning fire image based on the graphic included in the visible light image of the warning image. (ST26: reference graphic extraction step). Thus, in the initial reference graphic extraction step (ST15) and the reference graphic extraction step (ST26), the initial reference graphic and the reference graphic F are extracted from the visible light image captured by the visible light imaging means (imaging means 30). .

  In the reference graphic extraction process in the initial reference graphic extraction step (ST15) and the reference graphic extraction step (ST26), the initial reference graphic or the reference graphic F is at least the initial thermal image among the graphics included in the initial image or the warning image. Alternatively, the image is extracted including the outline of a graphic surrounding the fire heat H in the alert fire heat image or a graphic around the heat H.

  Subsequently, the heat-heat ratio calculation part 37 calculates the ratio of the area of the warning fire image (fire heat H) with respect to the area of the reference | standard figure F extracted in the reference | standard figure extraction process (ST26) as a heat-heat ratio (ST27: fire-heat ratio calculation process). . Next, the fire determination unit 38 determines whether or not the extracted reference graphic F matches the stored initial reference graphic (ST28).

  When the extracted reference graphic F matches the initial reference graphic (Yes in ST28), the fire determination unit 38 has increased the calculated current fire heat rate to a predetermined rate or higher than the stored initial fire heat rate. It is determined whether there is any (ST29: fire determination process). Then, in the fire determination step (ST29), when the calculated fire heat rate is increased to a predetermined rate or more from the initial fire heat rate (Yes), the fire determination unit 38 determines that a fire has occurred.

  When the extracted reference graphic F does not match the initial reference graphic (No in ST28), the fire determination unit 38 determines whether or not the fire heat H of the warning fire image matches the fire heat H of the initial fire image (ST30). ). Specifically, the fire determination unit 38 is based on the relative relationship between the extracted reference graphic F and the stored initial reference graphic, and the relative relationship between the warning fire image and the stored initial fire image. Then, it is determined whether or not the fire heat H of the warning fire image and the fire heat H of the initial fire image are the same.

  When the fire heat H of the warning fire image does not match the fire heat H of the initial fire image (No in ST30), it is determined that another fire heat H is detected, and the above-described initial heat storage process (initial heat storage process (ST4)). ) Is executed and the initial heat information and the warning direction are updated, the fire determination process is completed.

  When the fire heat H in the warning fire image matches the fire heat H in the initial fire image (Yes in ST30), it is determined that the mismatch of the fire heat H is caused by the movement of the position of the fire heat H, and the fire determination step (ST29) is executed. Is done. That is, when the reference graphic F is different from the initial reference graphic, the relative relationship between the fire heat H and the reference graphic F in the warning fire image and the relative relationship between the fire H and the initial reference graphic in the initial fire image are the same. (Yes in ST30) In the fire determination step (ST29), the fire heat rate calculated in the fire heat rate calculation step (ST27) is compared with the initial fire heat rate to determine whether or not a fire has occurred.

  If it is determined that a fire has occurred in the fire determination step (ST29) (Yes), then the fire extinguishing control unit 39 executes a fire extinguishing process (ST31: fire extinguishing process). As a result, the fire extinguishing agent 15 is injected from the injection port 21 toward the heat H. If it is determined that no fire has occurred in the fire determination step (ST29) (No), the fire determination process is completed while maintaining the initial heat information and the warning direction.

  In FIG. 13, when the fire heat H is not detected in the heat detection determination process (ST2) (No), or when the initial heat storage process process (ST4) is completed, or the fire determination process process (ST5) without being determined as a fire. When the process is completed, the monitoring control unit 34 determines whether or not other initial thermal information is stored (ST6). In the case where other initial heat information is stored, that is, when other heat H is detected (Yes in ST6), a fire determination processing step for determining whether the other heat H is a fire. (ST5) is executed.

  If no other initial heat information is stored, that is, if no other heat H is detected (No in ST6), or the fire determination processing step (ST5) for other heat H is not determined as a fire. When the process is completed, the monitoring control unit 34 controls the driving unit 25 via the drive control unit 32 to change the imaging direction of the imaging unit 30 to the next monitoring area (ST7), and returns to the beginning to monitor area imaging process. (ST1) is executed.

  As described above, when the heat H is not detected in all the monitoring areas, it is monitored whether or not there is the fire H in the next monitoring area. When the heat H is detected and the warning direction is stored, the warning area is detected. After confirming whether or not the fire heat H is a fire (fire determination process), the next monitoring area is monitored. That is, each time the imaging direction is one monitoring direction, the imaging unit 30 captures an image, and the fire detection unit 35 determines whether there is any fire H based on the captured image, and the fire H is detected. Then, in addition to a plurality of monitoring directions, control is performed so that the warning direction is also directed in order.

  As described above, the fire determination method for determining whether or not a fire has occurred in the house (in the room 2) in the fire extinguishing method of the present embodiment is a fire heat monitoring process (monitoring area imaging process (ST1), Fire detection detection step (ST2)), initial image imaging step (ST13), initial heat extraction step (ST14), initial reference graphic extraction step (ST15), initial heat ratio calculation step (ST16), warning image It includes an imaging step (ST22), a warning fire extraction step (ST23), a reference graphic extraction step (ST26), a heat ratio calculation step (ST27), and a fire determination step (ST29). As a result, it is possible to determine whether or not a fire has occurred in the house without requiring prior settings.

  Note that the control device 31 of the fire extinguishing system 1 is not limited to the form provided inside the base portion 17, and is configured by a computer (not shown) installed outside the room 2, for example, via a communication means such as a wireless LAN. The fire extinguishing apparatus 10, the driving means 25, and the imaging means 30 may be connected. Moreover, the power source of the fire extinguishing system 1 may be supplied from a commercial power source or a battery.

  INDUSTRIAL APPLICABILITY The present invention can extinguish a fire that has occurred in a house without requiring prior settings, and is useful in the field of disaster prevention equipment.

DESCRIPTION OF SYMBOLS 1 Fire extinguishing system 10 Fire extinguisher 15 Extinguishing agent 21 Injection port 21a Injection direction (direction of injection port)
27 Visible light camera 27a Optical axis (imaging direction)
28 Infrared transmission filter H, H1, H2a, H2b

Claims (4)

A fire extinguishing system that detects and extinguishes fires that occur inside the house,
A fire extinguisher having an injection port for injecting a fire extinguishing agent into the house;
Drive means for moving the direction of the injection port in a horizontal rotation direction and a vertical rotation direction;
An imaging means in which the imaging direction is the same as the direction of the ejection port, and the imaging direction moves integrally with the ejection port;
A drive control unit for controlling the drive means;
Based on the image captured by the imaging means, a fire detection unit that detects the heat,
A fire determination unit that determines whether or not the fire detected by the fire detection unit is a fire,
When the fire heat detection unit detects the fire heat, the drive control unit controls the drive means so that the imaging direction faces a warning direction that is the fire heat direction,
The fire determination unit determines whether the fire heat is a fire based on an image captured by the image capturing unit with the image capturing direction in the warning direction,
The fire extinguishing system, wherein when the fire determining unit determines that a fire has occurred, the fire extinguishing device is operated such that the extinguishing agent is injected. The imaging means includes
A visible light camera,
Filter insertion / extraction means for inserting / removing an infrared transmission filter in front of the visible light camera,
2. The fire extinguishing according to claim 1, wherein the fire detection unit detects fire based on an infrared image captured by the imaging unit with an infrared transmission filter inserted in front of the visible light camera. system.   The fire determination unit determines whether or not the fire is a fire based on the infrared image and a visible light image captured by the imaging unit without inserting an infrared transmission filter in front of the visible light camera. The fire extinguishing system according to claim 2, wherein the fire extinguishing system is determined. The drive control unit controls the drive means so that the imaging direction sequentially faces a plurality of preset monitoring directions,
Each time the imaging direction is directed to one monitoring direction, the imaging means captures an image, and the fire detection unit determines whether there is no heat based on the captured image,
The drive control unit controls the drive unit so that the warning direction is sequentially directed in addition to the plurality of monitoring directions when the fire heat detection unit detects the fire heat. Fire extinguishing system according to any of the above.

Images