JP4955307B2 - Fire monitoring equipment - Google Patents

Description

  The present invention relates to a fire monitoring apparatus that monitors a fire in a monitoring area.

  Conventionally, various fire detectors have been proposed, and infrared flame detectors and ultraviolet flame detectors are known as some of them. Infrared flame detectors detect the infrared rays contained in the light generated from the flames. The infrared rays from the flames flicker at a specific frequency different from the infrared rays emitted from artificial lighting and high-temperature objects, and from the flames. Infrared rays use a point having a high spectral intensity around a specific wavelength radiated from carbon dioxide (CO2), and detect a flame by distinguishing fire from other high-temperature objects. This infrared flame detector can be used as a human body detector to detect infrared rays emitted from the human body by adjusting the wavelength of the infrared rays to be detected with a filter, or emitted from infrared rays and flames emitted from the human body. It can be used as a human body fire detector that detects both infrared rays. For example, Patent Documents 1 to 3 describe an infrared sensor capable of detecting both a human body and a flame.

  The ultraviolet flame detector detects ultraviolet rays contained in the light generated from the flame. The ultraviolet ray detector receives and receives the ultraviolet rays in a discharge tube using an external photoelectric effect called UVtron (registered trademark). Ultraviolet rays are counted as pulses, and if this count exceeds a certain value, it is determined that a fire has occurred.

  Here, it is known that the main cause of fire is arson, and detection of arson is an important issue in fire prevention. Therefore, conventionally, a fire monitoring device particularly intended for arson has been proposed. As such a fire monitoring device for arson detection, based on the fact that arson is caused by artificial ignition, in addition to the flame detection function, it has a human body detection function, and the flame detection result and human body detection result by these There are some that perform arson determination in combination. For example, Patent Document 4 describes a fire monitoring device that performs a fire determination by combining the detection result of a human body sensor and the detection result of a flame sensor.

Japanese Patent Laid-Open No. 5-346994 JP-A-6-331755 Japanese Patent Laid-Open No. 10-283579 JP 2000-123266 A

  However, since the ultraviolet flame detector has high detection sensitivity, it can detect even a small flame in the early stage of arson, while reacting to various ultraviolet rays including static electricity of the human body, which may lead to false alarms. In addition, when the ultraviolet flame detector is set outdoors, it is preferable to install a battery-type ultraviolet flame detector that can omit wiring work. It is not practical to drive for a long period of time because it causes battery consumption.

  The present invention has been made in view of the above, and in a fire monitoring apparatus that performs fire determination by combining the detection result of the human body sensor and the detection result of the flame sensor, the false detection of the ultraviolet flame detector and battery saving The purpose is to provide a highly practical fire monitoring device.

To solve the above problems and achieve the object, the fire monitoring system according to claim 1, a fire monitoring apparatus for monitoring a fire in the monitored area, a fire that put in the monitoring area A fire detection means for detecting , a fire detection control means for turning on the fire detection means when the predetermined state is detected by a detection means for detecting a predetermined state other than a fire in the monitoring area, and the fire Fire determining means for determining the presence or absence of a fire in the monitoring area based on a sensing result in an ON state of the sensing means.

The fire monitoring device according to claim 2 is the fire monitoring device according to claim 1, wherein the detection means is provided in the fire monitoring device and detects a human body in the monitoring area. It is a human body detector .

The fire monitoring device according to claim 3 is the fire monitoring device according to claim 2 , wherein the detection means is a pyroelectric infrared sensor, and the fire detection means is an ultraviolet flame detector. It is characterized by this.

The fire monitoring device according to claim 4 is the fire monitoring device according to any one of claims 1 to 3 , wherein the fire detection control means detects the predetermined state by the detection means. In this case, after a predetermined fire detection standby time has elapsed, the fire detection means is turned on for a predetermined fire detection time .

Further, the fire monitoring apparatus according to claim 5 is the fire monitoring apparatus according to any one of claims 1 to 4 , wherein the fire detection control unit is configured to detect the detection unit when the fire detection unit is turned on. When the predetermined state is redetected by the detecting means before the elapse of a predetermined redetection monitoring time after the predetermined state is detected at the above, the time point of the redetection is used as a reference. The fire detection time is reset .

Further, the fire monitoring device according to claim 6 is the fire monitoring device according to claim 5 , wherein when the fire detection means is turned on, the predetermined state is detected by the detection means. When the predetermined state is detected again by the detection means after the elapse of a predetermined re-detection monitoring time from the detection, the fire detection means is turned off and the fire detection standby is started from the time of the OFF. After the elapse of time, the fire detection means is turned on for a predetermined fire detection time .

The fire monitoring device according to claim 7 is the fire monitoring device according to claim 6 , wherein the fire detection control means is configured to detect the predetermined state when the detection means detects the predetermined state. Immediately after the state is detected, the fire detection means is turned on for a predetermined temporary fire detection time shorter than the fire detection standby time .

Moreover, the fire monitoring apparatus according to claim 8 is the fire monitoring apparatus according to any one of claims 1 to 7, wherein the predetermined state is not detected by the detection means. Even in this case, the fire detection means is turned on every time a predetermined periodic monitoring interval comes .

  According to the first aspect of the present invention, when the predetermined state is detected by the detection means, the fire detection means is turned on, and a high-sensitivity detection means such as an ultraviolet sensor is used as the fire detection means. Even in this case, for example, the detection timing of the fire detection means can be controlled such that the ultraviolet sensor is turned on and fire detection is performed only when a human body is detected, and the possibility of misreporting can be reduced. In addition, by turning on the fire detection means only when necessary, and turning off the fire detection means in other cases, the power consumption of the fire monitoring device can be reduced. It can be driven.

According to the second aspect of the present invention, by using a human body detector as the detection means, the fire detection means can be turned on when a human body is detected, and the detection result of the human body and the detection of fire Based on the result, it is possible to make an arson determination. Particularly, since both the fire detection means and the human body detector are provided in the fire monitoring device, the fire monitoring function can be provided in one fire monitoring device, and the fire monitoring becomes easy.

According to the third aspect of the present invention, the detection means is a pyroelectric infrared sensor, and the fire detection means is an ultraviolet flame detector, so that the human body detection result of the pyroelectric infrared sensor is obtained. In response, the high-sensitivity ultraviolet flame detector can be turned on, and false alarms can be reduced even when the high-sensitivity ultraviolet flame detector is used.

Further, according to the present invention, the fire detection means is turned on after the fire detection standby time elapses. For example, immediately after a person enters the monitoring area, the fire detection is not performed and the room is kept in a constant state. By detecting fire after a while, even if a highly sensitive sensing means such as an ultraviolet sensor is used as a fire sensing means, the possibility of being affected by noise such as static electricity caused by people coming and going is reduced. And the possibility of false alarms can be reduced.

Further, according to the present invention described in claim 5, when a predetermined state is redetected before the redetection monitoring time elapses, for example, a person enters the monitoring area by resetting the fire detection time. After that, when the same person is operating, it is possible to detect the fire early by performing continuous fire detection.

According to the sixth aspect of the present invention, when a predetermined state is detected again after the re-detection monitoring time has elapsed, the fire detection means is turned off, and the fire detection standby time is set from the time of the OFF. By turning on the fire detection means after the elapse of time, for example, when a person enters the surveillance area and another person enters the room, fire detection is not performed immediately after that, and after a certain period of time has passed, a fire has occurred again. By performing the sensing, the possibility of being affected by noise such as static electricity caused by people coming and going can be reduced, and the possibility of false alarms can be reduced.

Further, according to the present invention as set forth in claim 7, when a predetermined state is detected, the fire detection means is turned on immediately after that, and when the fire is set off, the criminals leaving after the fire is set off. Since it is conceivable that the human body is detected by movement, it is possible to detect the arson more quickly by starting the monitoring of the flame using the action of the criminal immediately after the arson as a trigger.

According to the present invention as set forth in claim 8, regardless of whether or not a predetermined state is detected by the detection means, the detection means is turned on by detecting the fire detection means at regular monitoring intervals. When the detection means does not function for some reason even though there is a person who has entered the surveillance area, such as when there is a fault or when the arson is entered in such a manner that the detection means does not detect it. Even in such a case, if a fire is detected by the fire detection means, it is possible to prevent a misreport by determining that a fire has occurred.

  Hereinafter, embodiments of a fire monitoring apparatus according to the present invention will be described in detail with reference to the accompanying drawings. [I] First, the basic concept common to each embodiment was explained, then [II] the specific contents of each embodiment were explained, and [III] Finally, modifications to each embodiment were explained. To do. However, the present invention is not limited to each embodiment.

[I] Basic concept common to the embodiments First, the basic concept common to the embodiments will be described. The fire monitoring apparatus according to each embodiment is a fire monitoring apparatus for monitoring a fire in a monitoring area. Although this monitoring area is arbitrary, for example, the surroundings of a general house and a parking lot can be mentioned. In addition, unless otherwise specified, the physical quantity to be directly detected and the phenomenon to be monitored using this physical quantity are also arbitrary. For example, a fire is detected by detecting infrared rays, ultraviolet rays, smoke, or heat. The presence or absence of a human body is monitored by detecting the presence or absence of flames or detecting infrared rays or heat. In the following embodiment, an example in which an infrared detector or other disaster prevention device is used in combination with an ultraviolet flame detector will be described.

  One of the features of this fire monitoring device is that it controls on / off of the ultraviolet flame detector based on the detection result of the infrared detector. That is, normally, the presence of a human body in the monitoring area is monitored by an infrared sensor, and only when a human body is detected, the ultraviolet flame sensor is turned on to determine the presence or absence of flame. As a result, the ultraviolet flame detector is turned on only for a short time to prevent false alarms, and the power consumption of the battery-type ultraviolet flame detector is reduced.

[II] Specific contents of each embodiment [Embodiment 1]
Next, specific contents of each embodiment according to the present invention will be described. First, the specific content of Embodiment 1 is demonstrated. First, the configuration of the fire monitoring device will be described, and then the fire monitoring operation in the fire monitoring device will be described.

(Configuration of fire monitoring device 1)
FIG. 1 is a block diagram functionally conceptually showing the main electrical configuration of the fire monitoring apparatus 1 according to the first embodiment. The fire monitoring device 1 includes an infrared sensor unit 2, an ultraviolet sensor unit 3, an alarm unit 4, a transfer unit 5, and a control unit 6.

  The infrared sensor unit 2 detects a human body and a flame based on infrared rays emitted in the monitoring region, and corresponds to the detection means, the human body detector, and the pyroelectric infrared sensor in the claims. Specifically, the infrared sensor unit 2 includes a pyroelectric sensor 2a, an amplifier 2b, and a signal processing unit 2c. The pyroelectric sensor 2a is composed of various pyroelectric substances such as PZT (lead zirconate titanate) having pyroelectric characteristics, and absorbs infrared thermal energy to cause a temperature change. A proportionally induced detection signal is output to the amplifier 2b. The amplifier 2b amplifies the detection signal from the pyroelectric sensor 2a and outputs it to the signal processing unit 2c. The signal processing unit 2c determines the presence or absence of a human body or flame based on the detection signal from the amplifier 2b, and outputs the human body detection signal or the flame detection signal to the control unit 6.

  Here, the two types of detection of the human body and the flame by the infrared sensor unit 2 are achieved as follows. First, an optical filter (not shown) is provided on the light receiving surface of the pyroelectric sensor 2a. The optical filter transmits both infrared rays emitted from a human body and infrared rays emitted from a flame. For example, 4.4 μm or more. Transmits light in the wavelength band of. Then, the signal processing unit 2c compares the detection signal from the amplifier 2b with a predetermined first threshold value, and when the number of times that the detection signal exceeds the first threshold value exceeds a predetermined count number, the human body detects When the number of times that the detection signal exceeds the second threshold is equal to or greater than a predetermined count, it is determined that a flame has been detected and a flame detection signal is output. Output. In general, since infrared rays caused by flames are generated at a higher frequency than infrared rays caused by human bodies, the first threshold value and the second threshold value are set so that the first threshold value is smaller than the second threshold value. Can distinguish between human body and flame.

  The ultraviolet sensor unit 3 detects a flame based on the ultraviolet rays emitted in the monitoring area, and corresponds to the flame detecting means and the ultraviolet flame detector in the claims. Specifically, the ultraviolet sensor unit 3 includes an ultraviolet sensor 3a, a power supply control unit 3b, and a signal processing unit 3c. The ultraviolet sensor 3a is composed of a discharge tube called UV TRON (registered trademark). When ultraviolet rays hit a cathode inside a glass tube (not shown), photoelectrons emitted from the cathode by the photoelectric effect ionize the sealed gas. As a result, a discharge signal is output. The power supply control unit 3b is for turning on / off the ultraviolet sensor unit 3 by turning on / off the drive power supply to the ultraviolet sensor unit 3 and the signal processing unit 3c based on the control signal from the control unit 6. It corresponds to the fire detection control means in the claims. The signal processing unit 3c determines the presence or absence of flame based on the detection signal from the ultraviolet sensor 3a. For example, when the number of output of the detection signal from the ultraviolet sensor 3a exceeds a predetermined count, flame detection is performed. The signal is output to the control unit 6.

  The alarm unit 4 is an alarm means for performing an alarm sound or an alarm display when receiving an input of a control signal from the control unit 6, and includes, for example, a piezoelectric speaker and an LED (Light Emitting Diode). ing.

  The transfer unit 5 is a transfer unit that outputs a transfer signal to an external device of the fire monitoring apparatus 1, for example, a centralized monitoring panel (not shown) when receiving a control signal from the control unit 6. .

  The control unit 6 is a control unit that controls each unit of the fire monitoring apparatus 1 and includes a CPU (Central Processing Unit) and a program that is interpreted and executed by the CPU. In particular, the control unit 6 finally determines the presence or absence of a fire in the monitoring area based on the sensing result from the ultraviolet sensor unit 3 that is turned on in the infrared sensor unit 2. Corresponds to the fire judgment means.

(Fire monitoring operation)
Next, the fire monitoring operation in the fire monitoring apparatus 1 configured as described above will be described. The fire monitoring device 1 has four operation modes of “full arson detection mode”, “infrared fire detection mode”, “infrared human body detection mode”, and “energy saving arson detection mode”, and any one of these operation modes. Can be set by mode setting means such as a dip switch (not shown). Then, after the power supply to the fire monitoring device 1 is turned on, the control unit 6 identifies the operation mode based on the setting state of the mode setting means and performs control according to the set operation mode.

  In the full fire detection mode, the control unit 6 always turns on both the infrared sensor unit 2 and the ultraviolet sensor unit 3 and obtains an AND between the human body detection signal from the infrared sensor unit 2 and the flame detection signal from the ultraviolet sensor unit 3. It is determined that there was an arson only when Then, the control unit 6 outputs a control signal to the alarm unit 4 to give an alarm, and outputs a control signal to the transfer unit 5 to output a transfer signal to an external device.

  In the infrared detection mode, the control unit 6 always turns on only the infrared sensor unit 2 and always turns off the ultraviolet sensor unit 3, and a fire is detected when a flame detection signal is obtained by the infrared sensor unit 2. Is determined. Then, the control unit 6 outputs a control signal to the alarm unit 4 to give an alarm, and outputs a control signal to the transfer unit 5 to output a transfer signal to an external device.

  In the human body detection mode, the control unit 6 always turns on only the infrared sensor unit 2 and always turns off the ultraviolet sensor unit 3, and when a human body detection signal is obtained by the infrared sensor unit 2, a human body (intruder) Is determined to exist. And the control part 6 outputs a control signal only to the warning part 4, and makes a warning occur.

  Next, the energy saving arson detection mode will be described. FIG. 2 is a flowchart of the fire monitoring operation in the energy saving arson detection mode. First, the control unit 6 controls the power supply control unit 3 b to turn off the ultraviolet sensor unit 3 and performs monitoring only by the infrared sensor unit 2. In this way, the monitoring by only the infrared sensor unit 2 is performed for the following reason. That is, if the monitoring by the ultraviolet sensor unit 3 is always performed, the highly sensitive ultraviolet sensor unit 3 may cause a false alarm due to various noises such as illumination light. In addition, it is sufficient to detect the flame after detecting that a human body exists for detecting the fire. Furthermore, since a high voltage is required for monitoring by the ultraviolet sensor unit 3, it is preferable to reduce the energization time to the ultraviolet sensor unit 3 as much as possible particularly when the fire monitoring device 1 is of a battery type. For these reasons, until the human body is detected by the infrared sensor unit 2, monitoring by the ultraviolet sensor unit 3 is not performed, thereby preventing false alarms and reducing power consumption.

  And the control part 6 monitors the presence or absence of the input of the detection signal from the infrared sensor part 2 (step SA-1), and when there is an input of the detection signal (step SA-1, Yes), this If the detection signal is a human body detection signal (step SA-2, Yes), the process waits until a predetermined fire detection standby time t1 has elapsed (step SA-3). Then, after the fire detection standby time t1 has elapsed (step SA-3, Yes), the control unit 6 controls the power supply control unit 3b to turn on the ultraviolet sensor unit 3, thereby monitoring by the ultraviolet sensor unit 3. Is started (step SA-4). A time chart in this case is shown in FIG. As described above, the monitoring by the UV sensor unit 3 is not performed immediately after the human body detection signal is input, but the monitoring by the UV sensor unit 3 is performed immediately after the human body enters the monitoring region, without waiting for the fire detection standby time t1. This is because the high-sensitivity ultraviolet sensor unit 3 may generate false alarms due to various noises such as static electricity generated when a person entering the room takes off his jacket. For this reason, the possibility of misreporting is reduced by starting monitoring of the ultraviolet sensor unit 3 after waiting for the initial noise when a person enters the room to settle. The specific length of the fire detection standby time t1 is arbitrary, but is set to several minutes, for example.

  In FIG. 2, the monitoring by the ultraviolet sensor unit 3 started in this way is continuously performed for a predetermined fire detection time t2 (step SA-5). When no flame detection signal is input from the ultraviolet sensor 3 or no human body detection signal is re-input from the infrared sensor during the fire detection time t2 (Step SA-7, No, Step SA-9, No ), The control unit 6 controls the power supply control unit 3b to turn off the ultraviolet ray sensor unit 3, and again shifts to monitoring by the infrared ray sensor unit 2 (step SA-5, Yes, step SA-6). As described above, the monitoring by the ultraviolet sensor unit 3 is continuously performed for a predetermined fire detection time, thereby preventing false alarms and reducing power consumption as described above.

  On the other hand, if there is an input of a flame detection signal from the ultraviolet sensor unit 3 before the fire detection time t2 has elapsed (step SA-7, Yes), the control unit 6 may have fired in the monitoring area. The control signal is output to the alarm unit 4 to cause an alarm, and the control signal is output to the transfer unit 5 to output a transfer signal to an external device (step SA-8). In this way, it is determined that the possibility of arson is high because the human body is detected by the infrared sensor unit 2 first and the flame is detected by the ultraviolet sensor unit 3, so that the condition for determining arson is determined. This is because it is satisfied, and the possibility of misreporting can be reduced by issuing a report only when AND of the human body detection result and the flame detection result is obtained in this way.

  Alternatively, when the human body detection signal is input again from the infrared sensor unit 2 before the fire detection time t2 has elapsed (step SA-9, Yes), the control unit 6 determines that the input timing of the human body detection signal is It is determined whether or not the predetermined redetection monitoring time t3 has elapsed (step SA-10). This re-detection monitoring time t3 is a time measured with reference to the time when the human body detection signal is output from the infrared sensor unit 2 in step SA-2, and is a time longer than at least the fire detection standby time t1, and It is set as a time shorter than the sum of the fire detection standby time t1 and the fire detection time t2 (t1 <t3 <t1 + t2).

  When it is determined that the re-input timing of the human body detection signal is before the re-detection monitoring time t3 has elapsed (step SA-10, Yes), the control unit 6 determines the re-input timing of the human body detection signal. The fire detection time t2 is reset with respect to the time point (step SA-11), and the process proceeds to step SA-5. A time chart in this case is shown in FIG. Such control is performed for the following reason. That is, in this case, it is considered that the same person as the person detected in step SA-2 stays in the monitoring area and performs some operation. Therefore, it is not necessary to consider the initial noise when entering the room, and there is a possibility that this person will argue, so it is possible to detect arson quickly by continuously performing flame monitoring without stopping. Make it possible.

  On the other hand, when it is determined that the re-input timing of the human body detection signal is not after the re-detection monitoring time t3 but after the re-detection monitoring time t3 (No at Step SA-10), the control unit 6 turns on the power control unit 3b. After the control to turn off the energization to the ultraviolet sensor 3a (step SA-12), the process proceeds to step SA-3 and waits again for the fire detection standby time t1 to elapse, and then the power control unit 3b is turned on. By controlling and turning on the ultraviolet sensor unit 3, monitoring by the ultraviolet sensor unit 3 is started again (step SA-4). A time chart in this case is shown in FIG. Such control is performed for the following reason. That is, in this case, it is considered that a person different from the person detected in Step SA-2 has entered the monitoring area. Therefore, since it is preferable to monitor the arson under the same conditions as when the human body is first detected in the monitoring area, the process proceeds to step SA-3.

  Finally, the case where it is determined in step SA-2 that the detection signal from the infrared sensor unit 2 is not a human body detection signal but a flame detection signal (step SA-2, No) will be described. In this case, the control unit 6 determines that there is a high possibility that a fire has occurred in the monitoring area, regardless of whether or not the fire is set off, and proceeds to Step SA-8. Such control is basically performed by taking the AND of the infrared sensor unit 2 and the ultraviolet sensor unit 3 to perform the fire igniting determination, but the ultraviolet sensor unit 3 may not function due to some failure. For this reason, when flame detection is performed instead of human detection by the infrared sensor unit 2, it is determined that a fire has occurred regardless of the detection result of the ultraviolet sensor unit 3, thereby preventing misreporting.

(Effect of Embodiment 1)
As described above, according to the first embodiment, until the human body is detected by the infrared sensor unit 2, monitoring by the ultraviolet sensor unit 3 is not performed, thereby preventing false alarms and reducing power consumption. Can do. In addition, the monitoring by the UV sensor unit 3 is not started immediately after the human body detection signal is input, and the monitoring is started after the elapse of the fire detection waiting time t1, so that there is a possibility of false alarm due to noise when a person enters the room. Can be reduced. Moreover, when a human body is detected by the infrared sensor unit 2 and a flame is detected by the ultraviolet sensor unit 3, it is possible to reduce the possibility of misreporting by determining that the fire is set off. Further, when the human body detection signal is input again before the redetection monitoring time t3 elapses, it is possible to quickly detect the fire by continuously performing the flame monitoring without stopping. Furthermore, when the human body detection signal is input again after the redetection monitoring time t3 has elapsed, the flame monitoring is temporarily stopped, and after the fire detection waiting time t1 has elapsed, the monitoring is started again. The possibility of false alarms due to noise when entering the room can be reduced.

[Embodiment 2]
Next, the specific content of Embodiment 2 which concerns on this invention is demonstrated. In the second embodiment, flame monitoring is performed by the ultraviolet sensor even immediately after the human body is detected by the infrared sensor. The configuration of the second embodiment is substantially the same as the configuration of the first embodiment unless otherwise specified, and the configuration substantially the same as the configuration of the first embodiment is used in the first embodiment. The same reference numerals are given as necessary, and the description thereof is omitted.

(Configuration of fire monitoring device 20)
FIG. 6 is a block diagram functionally conceptually showing the main electrical configuration of the fire monitoring apparatus 20 according to the second embodiment. The fire monitoring apparatus 20 includes a control unit 7 instead of the control unit 6 of the first embodiment. The control unit 7 is a control unit that controls each unit of the fire monitoring apparatus 1 and includes a CPU and a program that is interpreted and executed by the CPU. In particular, the control unit 7 turns on the ultraviolet sensor unit 3 for a predetermined temporary fire detection time immediately after the human body is detected by the infrared sensor unit 2, and corresponds to the fire determination means in the claims. .

(Fire monitoring operation)
Next, the energy saving arson detection mode in Embodiment 2 will be described. FIG. 7 is a flowchart of the fire monitoring operation in the energy saving arson detection mode. Note that steps SB-1 to SB-12 correspond to steps SA-1 to SA-12 of the first embodiment, and a description thereof will be omitted. When the human body is detected by the infrared sensor unit 2 (step SB-2, Yes), the control unit 7 detects the infrared sensor unit 2 for a predetermined temporary fire detection without waiting for the fire detection standby time t1. It is turned on only for time t4 (steps SB-13 and SB-14). If there is no flame detection signal from the ultraviolet sensor 3 during the temporary fire detection time t4 (step SB-16, No, SB-14, Yes), the infrared sensor 2 is temporarily turned off. (Step SB-15), the ultraviolet sensor is turned on again after the fire detection standby time from Step SB-2 has elapsed (Steps SB-3, Yes, SB-4). The time chart corresponding to each case of FIGS. 3 to 5 under such control is shown in FIGS.

  On the other hand, when there is a flame detection signal from the ultraviolet sensor unit 3 during the temporary fire detection time t4 (step SB-16, Yes), the control unit 7 has a high possibility that the fire is performed in the monitoring area. The control signal is output to the alarm unit 4 to cause an alarm, and the control signal is output to the transfer unit 5 to output a transfer signal to an external device (step SB-8). This kind of control is performed when the arson is fired, because it is considered that the human body is detected by the movement of the criminal who leaves after arson. This is to detect arson more quickly. Note that the specific time of the temporary fire detection time t4 is arbitrary, but at least a time shorter than the fire detection standby time t1 (t4 <t1) is set.

(Effect of Embodiment 2)
Thus, according to the second embodiment, in addition to the effects as in the first embodiment, when a human body is detected by the infrared sensor unit 2, the infrared sensor unit 2 is set to a predetermined temporary fire detection time t4. By only turning it on, it is possible to start fire monitoring with the action of the criminal immediately after arson as a trigger and detect arson more quickly.

[Embodiment 3]
Next, the specific content of Embodiment 3 which concerns on this invention is demonstrated. In the third embodiment, on / off of the ultraviolet sensor unit 3 is controlled based on a human body detection result from an external signal source instead of the infrared sensor unit. The configuration of the third embodiment is substantially the same as the configuration of the first embodiment unless otherwise specified, and the configuration substantially the same as the configuration of the first embodiment is used in the first embodiment. The same reference numerals are given as necessary, and the description thereof is omitted.

(Configuration of the fire monitoring device 30)
FIG. 11 is a block diagram functionally conceptually showing the main electrical configuration of the fire monitoring apparatus 30 according to the third embodiment. The fire monitoring device 30 includes a signal input unit 8 instead of the infrared sensor unit 2 of the first embodiment. The signal input unit 8 is a receiving unit that receives a human body detection signal from the external signal source 9. Here, as the human body detection signal from the external signal source 9, any signal indicating the presence of a human body in the monitoring area can be used. For example, an automatic door provided at the entrance or inside of the monitoring area is activated. A door activation signal indicating that a human body has been detected by a human body detection sensor provided in a toilet inside the monitoring area, and that a human body has been detected by a crime prevention facility provided in the monitoring area This corresponds to a human body sensing signal indicating that a variety of equipment such as a vending machine has been used. The external signal source 9 corresponds to the detection means in the claims.

(Fire monitoring operation)
In such a configuration, the control unit 6 is based on the human body detection signal input from the external signal source 9 to the signal input unit 8 instead of the human body detection signal from the infrared sensor unit 2 of the first embodiment. The same control as in the first embodiment is performed.

(Effect of Embodiment 3)
Thus, according to the third embodiment, in addition to the effects as in the first embodiment, the same control as in the first embodiment can be performed based on the signal from the external signal source 9, and the infrared sensor unit The configuration of the fire monitoring device 30 can be simplified by omitting 2.

[Embodiment 4]
Finally, the specific content of Embodiment 4 which concerns on this invention is demonstrated. In the fourth embodiment, the ultraviolet sensor unit 3 is automatically turned on / off at predetermined time intervals regardless of the human body detection result of the infrared sensor unit. The configuration of the fourth embodiment is substantially the same as the configuration of the first embodiment unless otherwise specified, and the configuration substantially the same as the configuration of the first embodiment is used in the first embodiment. The same reference numerals are given as necessary, and the description thereof is omitted.

(Configuration of the fire monitoring device 40)
FIG. 12 is a block diagram functionally conceptually showing the main electrical configuration of the fire monitoring apparatus 40 according to the fourth embodiment. The fire monitoring device 40 includes a control unit 41 instead of the control unit 6 of the first embodiment.

(Fire monitoring operation)
Next, among the fire monitoring operations in the fourth embodiment, the energy saving arson detection mode will be described. FIG. 13 is a flowchart of the fire monitoring operation in the energy saving arson detection mode. Note that steps SC-1 to SC-12 correspond to steps SA-1 to SA-12 of the first embodiment, and a description thereof will be omitted. Even if the human body is not detected by the infrared sensor unit 2 (step SC-1, No), the control unit 41 performs the step every time the predetermined regular monitoring interval t5 arrives (step SC-17, Yes). Shifting to SC-4, the infrared sensor unit 2 is turned on for a predetermined fire detection time t2. Such control is performed when the infrared sensor unit 2 has some trouble, when the fire fighter enters the monitoring area at a very slow speed that is not detected by the pyroelectric sensor 2a, or Since it is possible that the infrared sensor unit 2 does not function for some reason even though there is a person who has entered the monitoring region, such as when entering a monitoring region with a low-temperature object facing the infrared sensor unit 2 This is because when the ultraviolet sensor unit 3 is turned on regardless of the detection result of the sensor unit 2 and a flame is detected by the ultraviolet sensor unit 3, it is determined that a fire has occurred, thereby preventing a false alarm. The specific time of the regular monitoring interval t5 is arbitrary, but at least a time longer than the fire detection standby time t1 and the fire detection time t2 is set (fire detection standby time t1 <periodic monitoring interval t5, fire detection time t2 < Regular monitoring interval t5). Further, the regular monitoring interval t5 is not necessarily constant. For example, the ultraviolet sensor unit 3 is turned on every 5 minutes in the daytime in conjunction with a clock or an illuminance sensor, and the ultraviolet sensor unit 3 every minute during the nighttime. By turning on, the daytime alertness and the nighttime alertness may be changed.

[III] Modifications to Embodiments Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. Can be arbitrarily modified and improved. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved.

(Combination of each embodiment)
The configuration and control shown in each embodiment can be combined with each other. For example, in addition to the control operation shown in the second embodiment, as shown in the fourth embodiment, the infrared sensor unit 2 is turned on for a predetermined fire detection time t2 every time the regular monitoring interval t5 arrives. You may do it.

  The fire monitoring device according to the present invention is used as a device for monitoring a fire, in particular, a device for monitoring arson, and is useful for preventing false alarms of the sensor and saving battery power.

It is a block diagram which shows functionally the main electrical structures of the fire monitoring apparatus which concerns on Embodiment 1 of this invention. It is a flowchart of the fire monitoring operation | movement in an energy saving arson detection mode. It is a time chart at the time of turning on an ultraviolet sensor part after progress of the fire detection waiting time. It is a time chart when a human body detection signal is input again before progress of redetection monitoring time. It is a time chart when a human body detection signal is input again after progress of redetection monitoring time. It is a block diagram which shows the main electrical structures of the fire monitoring apparatus which concerns on Embodiment 2 functionally conceptually. It is a flowchart of the fire monitoring operation | movement in an energy saving arson detection mode. It is a time chart at the time of turning on an ultraviolet sensor part after progress of the fire detection waiting time. It is a time chart when a human body detection signal is input again before progress of redetection monitoring time. It is a time chart when a human body detection signal is input again after progress of redetection monitoring time. It is a block diagram which shows the main electrical structures of the fire monitoring apparatus which concerns on Embodiment 3 functionally conceptually. It is a block diagram which shows the main electrical structures of the fire monitoring apparatus which concerns on Embodiment 4 functionally conceptually. It is a flowchart of the fire monitoring operation | movement in an energy saving arson detection mode.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 20, 30, 40 Fire monitoring apparatus 2 Infrared sensor part 2a Pyroelectric sensor 2b Amplifier 2c Signal processing part 3 Ultraviolet sensor part 3a Ultraviolet sensor 3b Power supply control part 3c Signal processing part 4 Alarm part 5 Transfer part 6, 7, 41 Control unit 8 Signal input unit 9 External signal source

Claims (8)

A fire monitoring device for monitoring a fire in a monitoring area,
Fire detection means for detecting a fire in the monitoring area;
A fire detection control unit that turns on the fire detection unit when the predetermined state is detected by a detection unit that detects a predetermined state other than a fire in the monitoring area;
Fire determination means for determining the presence or absence of a fire in the monitoring area, based on a detection result in an on state of the fire detection means;
A fire monitoring device comprising: The detection means is provided in the fire monitoring device, and is a human body detector that detects a human body in the monitoring area;
The fire monitoring device according to claim 1. The detection means is a pyroelectric infrared sensor,
The fire detection means is an ultraviolet flame detector;
The fire monitoring device according to claim 2 . The fire detection control means turns on the fire detection means for a predetermined fire detection time after a predetermined fire detection standby time when the predetermined state is detected by the detection means;
The fire monitoring device according to any one of claims 1 to 3, wherein When the fire detection control unit is turned on, the detection unit detects the predetermined state before the elapse of a predetermined redetection monitoring time after the detection unit detects the predetermined state. Is detected again, resetting the fire detection time with reference to the time of the re-detection,
The fire monitoring device according to any one of claims 1 to 4, wherein: The fire detection control means, when the fire detection means is turned on, the predetermined state is detected by the detection means after a predetermined re-detection monitoring time has elapsed since the predetermined state was detected by the detection means. If detected again, turn off the fire detection means and turn on the fire detection means for a predetermined fire detection time after elapse of the fire detection standby time from the time of the off,
The fire monitoring device according to claim 5 . When the predetermined state is detected by the detection unit, the fire detection control unit moves the fire detection unit to a predetermined temporary time shorter than the fire detection standby time immediately after the predetermined state is detected. Turn on only during the fire detection time,
The fire monitoring device according to claim 6 . The fire detection control means turns on the fire detection means every time a predetermined regular monitoring interval arrives, even when the detection means does not detect the predetermined state;
The fire monitoring device according to any one of claims 1 to 7, wherein

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