JP3150191U - Alarm - Google Patents

Abstract

The present invention provides an alarm device capable of preventing fire from occurring by deterring the cooperation between flame detection and a lighting device to more effectively threaten a fire fighter. An alarm device is installed outdoors or semi-outdoors, and monitors a fire in a monitoring area. The fire determination unit 26 determines a fire in a plurality of stages based on temporal changes in the detection signal of the flame detection unit 14, and determines a fire when the fire determination result at each stage satisfies a predetermined condition. The lighting control unit 32 is based on at least one fire determination result before the fire determination, for example, a first fire determination result by ignition of a lighter or the like, among the fire determinations of a plurality of stages determined by the fire determination unit 26. The lighting device 16 is driven. [Selection] Figure 1

Description

The present invention relates to an alarm device that monitors and copes with arson.

  In recent years, due to the large number of deaths due to house fires, the installation of fire alarms for houses has become mandatory, and a decrease in deaths due to house fires is expected.

  On the other hand, according to statistics, the number of building fires is about 33,000 / year, of which it is reported that the highest number is about 6,000 / year due to arson and suspicion of arson.

  As a method of monitoring such fire caused by arson, it is considered to install a flame detector that detects the flame caused by the fire in a place where it is easy to ignite, detect the fire caused by the arson in the initial stage, and give an alarm in the dwelling unit. It is done.

  Conventionally, there is a flame detector that detects infrared rays of a specific wavelength band emitted from a flame. In order to increase detection accuracy, a multi-wavelength flame detector is also known that detects infrared rays in a plurality of wavelength bands and processes the infrared signals of the respective wavelengths to determine flames (Patent Document 1). Some use an ultraviolet sensor (Patent Document 2) and others use both ultraviolet and infrared (Patent Document 3). Furthermore, there are those that detect flame flicker, which is said to be distributed in a frequency band near several hertz, with a circuit filter or the like, and those that analyze various flicker patterns by calculation or the like (Patent Document 4).

  There are outdoor flame sensors that use a combination of some of these flame detection principles, and there are also those that are used as fire discharge sensors by combining a human body sensor with this (Patent Documents 5 and 6).

On the other hand, lighting is considered to be effective for crime prevention such as arson at night, and a system for driving an illuminating device in conjunction with a human body sensor installed outdoors is well known.

JP 2001-249047 A Japanese Patent Laid-Open No. 06-290375 Japanese Patent Laid-Open No. 08-022584 JP 2000-057456 A JP 2007-317135 A JP 2000-123266 A

  However, in a system that drives a lighting device in conjunction with a conventional human body sensor, when the suspicious person approaches the monitoring area, the lighting device is turned on and illuminates to ignite the fire. Yes, if the lighting device is turned on and nothing else happens, the arson cannot be dismissed.

  In addition, the conventional flame detector is used to detect and warn of the situation where the fire is set off with a lighter or the like. Not obtained.

An object of the present invention is to provide an alarm device that can prevent fire from occurring by performing more effective threats to a fire fighter by devising cooperation between flame detection and a lighting device.

The present invention is an alarm device that is installed outdoors or semi-outdoors and monitors a fire in a monitoring area.
A flame detection unit that detects a flame and outputs a detection signal;
A fire determination unit that determines fires in multiple stages from temporal changes in the detection signal of the flame detection unit, and determines a fire when the fire determination result at each stage satisfies a predetermined condition;
A lighting device that illuminates part or all of the monitoring area;
A lighting control unit that drives the lighting device based on the result of at least one fire determination before reaching the fire determination among the fire determinations of a plurality of stages determined by the fire determination unit;
Is provided.

Here, the flame detector
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit performs a first-stage fire determination for determining a fire based on a detection signal from the ultraviolet sensor, and a second-stage fire determination for determining a fire based on a detection signal from the infrared sensor. Based on the fire judgment result of the stage, the fire is determined,
The lighting control unit drives the lighting device when a fire determination result of the first stage is obtained by the fire determination unit.

The flame detector
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit is a first-stage fire determination that determines that the detection signal from the ultraviolet sensor exceeds a predetermined reference, and a second-stage fire that determines that the detection signal from the infrared sensor exceeds a predetermined reference Make a decision, and determine the fire based on the result of the second stage fire decision,
The lighting control unit drives the lighting device when a fire determination result of the first stage is obtained by the fire determination unit.

The flame detector
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit determines that the detection signal from the ultraviolet sensor exceeds the predetermined standard and that the predetermined fluctuation frequency specific to the flame can be obtained from the detection signal from the infrared sensor and the detection signal from the infrared sensor. To determine the second stage fire, determine the fire based on the second stage fire determination result,
The lighting control unit drives the lighting device when the determination unit obtains the first-stage fire determination result.

The flame detector
It has multiple infrared sensors that detect infrared rays of different wavelengths from the flame and output detection signals,
The fire determination unit is configured to determine a flame from a correlation between detection signals of a plurality of infrared sensors, and a predetermined fluctuation frequency specific to the flame from a detection signal from at least one of the plurality of infrared sensors. Make a second-stage fire judgment to determine that the fire is obtained, and determine the fire based on the second-stage fire judgment result,
The lighting control unit drives the lighting device when a fire determination result of the first stage is obtained by the fire determination unit.

The flame detector
A first infrared sensor that detects an infrared ray having a predetermined wavelength corresponding to CO ₂ resonance radiation emitted from the flame and outputs a detection signal;
A second infrared sensor that detects infrared light of a wavelength other than a predetermined wavelength corresponding to CO ₂ resonance radiation and outputs a detection signal;
With
The fire determination unit includes a first stage fire determination for determining that the detection signal from the first infrared sensor exceeds a predetermined reference and the detection signal from the second infrared sensor is equal to or lower than the predetermined reference; Perform a second stage fire determination to determine that a predetermined fluctuation frequency specific to the flame can be obtained from the detection signal from the sensor, and determine the fire based on the second stage fire determination result,
The lighting control unit drives the lighting device when a fire determination result of the first stage is obtained by the fire determination unit.

The alarm device of the present invention further includes
A human sensor that detects a person in the monitoring area and outputs a detection signal;
A human determination unit that determines the presence or intrusion of a person from the detection signal of the human sensor;
Provided,
The lighting control unit is based on the result of at least one fire determination before the fire determination among the multiple-stage fire determinations determined by the fire determination unit when the person determination unit determines the presence or intrusion of the person. To drive the lighting device.

The alarm device of the present invention further includes
A time acquisition unit for acquiring the current time;
A time management unit that sets a predetermined time zone as a control effective time zone of the lighting device;
Provided,
The lighting control unit is a lighting device based on a result of at least one fire determination before reaching a fire determination among a plurality of stages of fire determination determined by the fire determination unit in the control effective time zone set by the time management unit Drive.

The alarm device of the present invention further includes
A brightness sensor that detects the brightness of the monitoring area and outputs a detection signal;
A light / dark determination unit for determining a decrease in brightness of the monitoring area from the detection signal of the light / dark sensor;
Provided,
The lighting control unit determines at least one of the fire determinations before reaching the fire determination among the multiple levels of fire determinations determined by the fire determination unit when the brightness decrease of the monitoring area is determined by the light / dark determination unit. The lighting device is driven based on the result.

  The lighting control unit stops driving the lighting device when the fire determination unit does not determine a fire after driving the lighting device.

The alarm device of the present invention is further provided with a communication unit that transmits and receives signals to and from other alarm devices,
When the lighting control unit starts driving the lighting device, the communication unit transmits a lighting driving start signal to another alarm device, while the communication unit receives a lighting driving start signal from the other alarm device. The lighting device is driven.

The alarm device of the present invention further includes a communication unit for transmitting and receiving signals to and from other alarm devices,
When the lighting control unit determines a fire in the fire determination unit, the communication unit transmits a lighting drive start signal to another alarm device, while the communication unit receives a lighting drive start signal from another alarm device, Drive your own lighting device.

  When the illumination control unit receives an illumination drive start signal from another alarm device, the illumination control unit drives its own illumination device after a predetermined delay time has elapsed since the signal reception.

When the illumination control unit receives an illumination drive stop signal from another alarm device, the illumination control unit stops driving the lighting device itself for a predetermined period.

  According to the alarm device of the present invention, it is possible not only to rely on detection of the human body, but to perform a more effective threat to the arson by driving the lighting device immediately after the lighter is ignited. it can.

  In addition, after the lighting device is driven, a detailed fire determination is made in multiple stages before a fire is determined from the flame detection signal and an alarm is issued, so it can be immediately threatened but annoying. The possibility of false alarms does not increase.

In addition, by using a human sensor, a light / dark sensor, or time zone management in combination, it is possible to further narrow down the driving conditions of the lighting device and suppress unnecessary lighting control.

The block diagram which showed 1st Embodiment of the alarm device by this invention which judges a fire from the fluctuation frequency of an ultraviolet-ray, infrared rays, and a flame Graph showing the wavelength distribution of the light energy emitted from the flame The flowchart figure which showed the fire monitoring process by 1st Embodiment of FIG. The block diagram which showed 2nd Embodiment of the alarm device by this invention which judges a fire from the multiwavelength of infrared rays, and the fluctuation frequency of a flame The flowchart figure which showed the fire monitoring process by 2nd Embodiment of FIG. The block diagram which showed 3rd Embodiment of the alarm device by this invention which used the human sensor together The flowchart figure which showed the fire monitoring process by 3rd Embodiment of FIG. The block diagram which showed 4th Embodiment of the alarm device by this invention which set the effective time zone which drives an illuminating device. The flowchart figure which showed the fire monitoring process by 4th Embodiment of FIG. The block diagram which showed 5th Embodiment of the alarm device by this invention which used the brightness sensor together. The flowchart figure which showed the fire monitoring process by 5th Embodiment of FIG. The block diagram which showed 6th Embodiment of the alarm device by this invention which drives an illuminating device in conjunction with another alarm device. The flowchart figure which showed the fire monitoring process by 6th Embodiment of FIG.

  FIG. 1 is a block diagram showing a first embodiment of an alarm device according to the present invention. In this first embodiment, a fire is judged from the fluctuation frequencies of ultraviolet rays, infrared rays and flames. And

  In FIG. 1, the alarm device 10 is installed on the wall surface of a building with a guard area such as an eaves area, a garbage collection place, a storage area, a miscellaneous building, an apartment staircase, and a landing that are said to be easily arson.

  The alarm device 10 includes a processor 12, a flame detection unit 14, a lighting device 16, an acoustic alarm unit 18, and a transfer unit 20.

  In this embodiment, the flame detector 14 is provided with an ultraviolet sensor 22 and an infrared sensor 24. The ultraviolet sensor 22 uses, for example, a photoelectric tube for detecting ultraviolet rays known as UV TRON (registered trademark), detects ultraviolet rays emitted from a flame via a detection circuit (not shown), and outputs a detection signal.

  For example, a pyroelectric sensor is used as the infrared sensor 24. The infrared sensor 24 detects infrared rays output from the flame, and outputs a detection signal through a detection circuit (not shown).

FIG. 2 is a graph showing the wavelength distribution of light energy emitted from the flame. The distribution of the wavelength spectrum from the flame is distributed from the ultraviolet region through the visible region to the infrared region shown in FIG. In the spectrum distribution in the infrared region, infrared having a peak level in the vicinity of 4.3 (μm) due to resonance emission of carbon dioxide (CO ₂ ) generated during combustion is obtained as a spectrum peculiar to the flame. Separately from this, it is known that ultraviolet rays of about 200 nm are emitted from the flame.

  Referring again to FIG. 1, the lighting device 16 includes a lighting device 16 that illuminates a part or all of a warning area monitored by the alarm device 10 by the flame detection unit 14. As the illuminating device 16, for example, a white LED can be used, and continuous lighting or intermittent lighting can be performed as necessary. For simplicity, the illumination drive circuit is not shown.

  The sound alarm unit 18 is provided with a buzzer, a speaker, and the like, and outputs an alarm sound as necessary. The transfer unit 20 outputs a fire transfer signal when a fire is determined by the alarm device 10 to an external device such as a monitoring panel installed in a dwelling unit, and causes a fire alarm.

  The processor 12 includes a CPU, a ROM, a RAM, an AD conversion port, and various input / output ports. The functions of the fire determination unit 26 and the illumination control unit 32 are realized by executing a program by the CPU.

  The fire determination unit 26 determines a fire in a plurality of stages from the detection signal from the flame detection unit 14, and determines a fire when the fire determination result at each stage satisfies a predetermined condition. In the case of the embodiment of FIG. 1, since the ultraviolet sensor 22 and the infrared sensor 24 are provided in the flame detection unit 14, for example, fire determination is performed over the following three stages to determine the fire.

  (1) In the first stage fire determination, it is determined that the detection signal from the ultraviolet sensor 22 exceeds a predetermined reference.

  (2) In the second stage fire determination, it is determined that the detection signal from the infrared sensor 24 exceeds a predetermined reference.

  (3) In the third stage fire determination, the frequency is analyzed from the detection signal of the infrared sensor 24, and it is determined that a frequency signal around 2 Hz known as a predetermined fluctuation frequency unique to the flame is obtained more than a predetermined value. .

  Here, in general, an ultraviolet sensor can detect ultraviolet rays in a very short time from a small flame by a lighter or the like. Infrared sensors detect relatively medium scale flames. In order to analyze the signal from the infrared sensor, a predetermined processing time is required because, for example, the flickering frequency of the flame is as slow as about 2 Hz.

  Corresponding to these three stages of fire determination, the first stage fire determination and the second stage fire determination are performed by the flame determination unit 28. The third stage fire determination is performed by the flicker determination unit 30.

  When the flicker frequency component is extracted by the circuit filter of the infrared detection circuit, the second stage fire determination and the third stage fire determination are performed at the same time, and the flicker determination unit 30 can be omitted at this time. .

  The lighting control unit 32 drives the lighting device 16 based on the result of at least one fire determination before reaching the fire determination among the multiple stages of fire determination determined by the fire determination unit 26. In the case of the embodiment of FIG. 1, since the three-stage fire determination is performed as described above, when it is determined that the detection signal from the first-stage ultraviolet sensor 22 exceeds a predetermined threshold value, The lighting device 16 is driven to illuminate the warning area.

  The timing at which the lighting device 16 is driven by the lighting control unit 32 is such that, for example, when the arson enters the alert area and ignites the lighter, the detection signal of the ultraviolet sensor 22 having good sensitivity to a small flame is generated. When the predetermined threshold is exceeded, the lighting device 16 is driven, and when the arson is ignited by a lighter or the like, the alarm device 10 illuminates immediately, and the light is turned on when the lighter ignites to ignite. It is possible to exert an intimidating effect by, for example, effectively threatening the arson and deterring the arson.

  On the other hand, after the first stage fire determination based on the detection signal of the ultraviolet sensor 22 is performed by the fire determination unit 26 in the fire determination unit 26, if the fire determination is not reached even after a predetermined time has elapsed, The driving lighting device is stopped.

  FIG. 3 is a flowchart showing an example of the outline of the fire monitoring process according to the first embodiment of FIG. 1, and is a control process of the fire determination unit 26 and the illumination control unit 32 by the processor 12. In FIG. 3, when the power of the alarm device 10 is turned on, the processor 12 executes initialization and self-diagnosis processing in step S1, and proceeds to step S2 if normal, and the ultraviolet detection value from the ultraviolet sensor 22 is a predetermined threshold value. Whether or not it is over is monitored.

  When the detection value from the ultraviolet sensor 22 is equal to or greater than the threshold value, the process proceeds to step S3, and since it is the first-stage fire determination result, the illumination control unit 32 drives the illumination device 16 to illuminate the alert area. The driving of the lighting device in this case may be continuous lighting, or may be intermittent lighting to enhance the threatening effect. Further, if necessary, a relatively low volume alarm sound or a short time alarm sound may be emitted from the acoustic alarm unit 18 to enhance the threatening effect against the arson as well as lighting.

  Subsequently, in step S4, a second-stage fire determination is made as to whether or not the detection value of the infrared sensor 24 is equal to or greater than a predetermined threshold value. When the detection value of the infrared sensor 24 is equal to or greater than the threshold value, the process proceeds to step S6. Flicker frequency analysis will be performed.

  If the detection value of the infrared sensor is less than the predetermined value in step S4, the elapse of the predetermined time is checked in step S5. When the predetermined time elapses without the infrared detection value exceeding the reference value, the process proceeds to step S12. It advances and stops the illuminating device 16 which is driving.

  In the flicker frequency analysis in step S6, the detection signal from the infrared sensor 24 is frequency-analyzed by, for example, fast Fourier transform, and whether or not the flicker frequency characteristic peculiar to flame is obtained as an analysis result in step S7, that is, the flame peculiar. It is determined whether or not the flicker frequency is obtained, and if the flicker frequency unique to the flame is obtained, it is determined that the third-stage determination result is obtained, the process proceeds to step S9, the fire is determined, and the transfer unit 20 is determined in step S10. Output to an external alarm panel or sound device to cause a fire alarm.

  Here, if the flicker frequency specific to the flame is not determined in step S7, the elapse of the predetermined time is checked in step S8, and if the predetermined time elapses without determining the flicker frequency specific to the flame, the process proceeds to step S12. It advances and stops the illuminating device 16 which is driving.

  When the flicker frequency peculiar to flame is determined in step S7, the fire determination process is performed in step S9, and after the fire transfer is performed in step S10, the recovery operation is waited for in step S11 and the recovery operation is performed. Then, after stopping the driving of the illumination device 16 in step S12, monitoring of the detection signal from the ultraviolet sensor 22 in step S2 starts again.

  In the present embodiment, the vicinity of 4.3 (μm) is described as an example of the signal wavelength band extracted from the infrared sensor 24. However, other wavelength bands may be selected, or a combination of two wavelength bands or 3 The first stage fire determination may be performed based on a signal from one wavelength band. A combination of these wavelengths can be appropriately selected from known techniques. Further, the second fire determination by the flicker analysis can be appropriately selected from known techniques.

  FIG. 4 is a block diagram showing a second embodiment of an alarm device according to the present invention. In this second embodiment, a fire is judged from the multi-wavelength of infrared and the fluctuation frequency of flame. Features.

  In FIG. 4, the alarm device 10 is provided with a processor 12, a flame detection unit 14, an illumination device 16, an acoustic alarm unit 18, and a transfer unit 20, and this point is basically the first implementation of FIG. Although it is the same as a form, in the 2nd embodiment, the 1st infrared sensor 24a and the 2nd infrared sensor 24b are provided in the flame detection part 14. FIG.

The first infrared sensor 24a detects infrared rays in the vicinity of a wavelength λ1 = 4.3 (μm), which is a peak level due to CO ₂ resonance unique to a flame in the infrared region shown in FIG. Following translucent window 34 which is disposed, by disposing the .lambda.1 optical wavelength filter 36a to be incident infrared centered wavelength of CO ₂ resonance wavelength λ1 = 4.3 (μm), CO 2 infrared resonance wavelength To detect.

  On the other hand, the second infrared sensor 24b is an infrared sensor that detects infrared rays having a predetermined wavelength λ2 that deviates from the vicinity of the CO2 resonance wavelength λ1 = 4.3 (μm) in FIG. 2, for example, λ2 = 5 (μm). Therefore, a λ2 optical wavelength filter 36b that transmits infrared rays in the vicinity of the wavelength λ2 = 5 (μm) is disposed after the light-transmitting window 34 so as to detect infrared rays in the vicinity of λ2 = 5 (μm). As the translucent window 34, sapphire glass etc. are applicable, for example. In the embodiment of FIG. 1, an appropriate translucent window that can transmit ultraviolet rays and infrared rays can be used.

The fire determination unit 26 provided as a function realized by execution of a program by the CPU of the processor 12 is provided with a flame determination unit 28 and a flicker determination unit 30. The flame determination unit 28 obtains an infrared detection signal of CO ₂ resonance wavelength λ1 or more from the first infrared sensor 24a provided in the flame detection unit 14, and deviates from the CO ₂ resonance wavelength λ1 from the second infrared sensor 24b. The first-stage fire determination is performed on the condition that the infrared ray of λ2 = 5 (μm) is below a predetermined value.

  When the first-stage fire determination is performed by the flame determination unit 28, the illumination control unit 32 drives the illumination device 16. When the first-stage fire determination by the flame determination unit 28 is completed, the second-stage fire determination is performed by the flicker determination unit 30 to determine the flicker frequency distribution characteristics and the like around the flicker frequency 2 Hz inherent to the flame. When the flicker frequency characteristic peculiar to the flame is determined in the fire determination in the second stage, the fire is determined and a fire alarm signal is output from the transfer unit 20 to an external monitoring panel or the like to cause a fire alarm. This flicker determination may be performed only for the signal of λ1 from the infrared sensor 24a.

  FIG. 5 is a flowchart showing a fire monitoring process according to the second embodiment of FIG. 4, and is a control process by the processor 12 of FIG. In FIG. 5, when the power of the alarm device 10 is turned on, the processor 12 performs initialization and self-diagnosis in step S21, and then, in step S22, the first infrared sensor 24a and the second infrared sensor provided in the flame detection unit 14 It is determined whether or not the wavelength detection pattern by 24b matches the flame.

Specifically, the detection signal of the first infrared sensor 24a and the detection signal of the second infrared sensor 24b are read from the AD conversion port of the processor 12, and the detection signal of the CO ₂ resonance wavelength λ1 which is the detection signal of the first infrared sensor 24a. Is obtained when the infrared detection signal of λ2 wavelength outside the CO ₂ resonance wavelength of the second infrared sensor 24b is equal to or lower than the predetermined reference, and is matched with the flame wavelength detection pattern. The fire determination is performed, and the process proceeds to step S23 where the lighting device 16 is driven to illuminate the warning area. At this time, if necessary, a relatively low-volume alarm sound or a short-time alarm sound may be emitted from the acoustic alarm unit 18 to further enhance the threatening effect against the arson.

  Subsequently, in step S24, a flicker frequency analysis, which is a second-stage fire determination, is performed. In step S24, if the flicker frequency characteristic specific to the flame is determined from the analysis result, the process proceeds to step S27, where a fire is determined, and in step S28. A fire detection signal is output from the transfer unit 20 to an external monitoring panel, an audio device, or the like, and an alarm is issued.

  On the other hand, if the flicker frequency specific to the flame is not determined in step S25, the elapse of the predetermined time is checked in step S26, and when the predetermined time elapses, the process proceeds to step S30. Stop driving the lighting device.

  Further, after alarming by performing a fire report based on the fire determination in step S28, it is determined whether or not there is a recovery operation in step S29, and when the recovery is performed, the lighting device 16 driven in step S30 is stopped. Then, the process returns to the first-stage fire determination by the infrared sensors 24a and 24b in step S22 again.

  In the present embodiment, the combination of the vicinity of 4.3 (μm) and the vicinity of 5 (μm) has been described as an example of the signal wavelength band extracted from the infrared sensors 24a and 24b, but for example, the vicinity of 4.3 (μm) and 3. It may be a combination of other wavelength bands, such as around 8 (μm). For example, signals from three wavelength bands near 3.8 (μm), 4.3 (μm), and 5 (μm) are used. Based on this, a first-stage fire determination may be performed. A combination of these wavelengths can be appropriately selected from known techniques. Further, the second fire determination by the flicker analysis can be appropriately selected from known techniques.

  FIG. 6 is a block diagram showing a third embodiment of an alarm unit according to the present invention. The third embodiment is characterized in that a human sensor is used in combination.

  In FIG. 6, the alarm device 10 is provided with a processor 12, a flame detection unit 14, a lighting device 16, an acoustic alarm unit 18, and a transfer unit 20, and this configuration is the same as that of the first embodiment of FIG. 1. In addition to this, a human sensor 38 is further provided. Again, a translucent window that transmits the respective detection wavelengths can be arranged on the front face of each sensor as required.

  The human sensor 38 detects infrared rays emitted from a human body that enters or exists in the alert area and outputs a detection signal. As the human sensor 38, an infrared sensor using a pyroelectric element can be used. Accordingly, the detection signal of the infrared sensor 24 can also be used as the human sensor 38 by selecting the wavelength band or the like.

  The fire determination unit 26 of the processor 12 is provided with a flame determination unit 28 and a flicker determination unit 30. In this embodiment, when the detection signal from the ultraviolet sensor 22 becomes a predetermined value or more in the flame determination unit 28. The first-stage fire determination for determining a fire, and the subsequent determination by the flicker determination unit 30 for determining the flicker frequency inherent to the flame from the detection signal from the infrared sensor 24 is the second-stage fire determination. The fire is judged.

  Along with the presence of the human sensor 38, the processor 12 is further provided with a human determination unit 40. The person determination unit 40 determines the entry of a person or the presence of a person in the alert area from the detection signal from the human sensor 38.

  The lighting control unit 32 drives the lighting device 16 based on the determination result of the fire determination unit 26 and the determination result of the person determination unit 40. That is, when the fire determination unit 28 provided in the fire determination unit 26 obtains a first-stage fire determination result in which the detection signal from the ultraviolet sensor 22 is equal to or higher than a predetermined reference, the human determination unit 40 receives the human sensor 38. When the presence of an intruder or person in the alert area based on the detection signal is determined, the illumination device 16 is driven to illuminate the alert area. That is, for example, when the human sensor 38 detects the intrusion of the human body into the alert area, and then a fire (flame) is detected in the first fire determination by the lighter or the like ignited by a signal from the ultraviolet sensor, the lighting device 16 To illuminate the alert area.

  Thus, by using the determination result of the presence of an intruder or a person in the alert area in combination with the control of the lighting device 16, even if there is an erroneous determination of the first stage fire determination in the fire determination section 26, the person determination section 40. In the case where there is no person based on the determination result, it is possible to prevent the illumination device 16 from being erroneously driven by the illumination control unit 32 and to suppress unnecessary illumination control.

  FIG. 7 is a flowchart showing an outline of a fire monitoring process example according to the third embodiment of FIG. 6, and is a control process by the processor 12 of FIG. In FIG. 7, when the power of the alarm device 10 is turned on, the processor 12 performs initialization and self-diagnosis in step S31. If there is no error, the processor 12 proceeds to step S32, and the person determination unit 40 detects it from the human sensor 38. Based on the presence / absence of the presence sensor detection, that is, whether there is an intruder in the alert area or whether there is a person, and if a determination result indicating presence of the presence sensor is obtained, the process proceeds to step S33, and the outside line sensor 22 A first-stage fire determination is made to determine whether the detected value from is greater than or equal to a predetermined threshold.

  Then, it progresses to step S35, the illuminating device 16 is driven, a warning area is illuminated, and the illuminating device 16 can be driven immediately after ignition of a lighter etc., and an arson can be threatened and removed.

  If it is not determined in step S33 that the ultraviolet sensor is detected, the process waits for a predetermined time in step S34. If no ultraviolet sensor is detected, the process returns to the first stage fire determination in step S32.

  Further, since a general human sensor intermittently outputs a detection signal when a person operates in the monitoring area, step S34 is deleted, and if there is no ultraviolet sensor detection in step S33, the process directly returns to step S32. You may do it. Further, the detection determination of the ultraviolet sensor and the detection determination of the human body may be reversed.

  After driving the illuminating device 16 in step S35, flicker frequency analysis is performed using a signal from the infrared sensor 24 which is a second-stage fire determination in step S36, and when the flicker frequency characteristic unique to the flame is determined in step S38. In step S39, a fire is determined, and in step S40, a fire alarm is issued, and a fire alarm is issued from an external monitoring panel or sound device.

  Subsequently, when the restoration operation is determined in step S41, the driving of the lighting device 16 is stopped in step S42, and the state returns to the human sensor monitoring state in step S32. If the flicker frequency specific to the flame is not determined from the flicker frequency analysis result in step S38, the process waits for a predetermined time in step S37 and proceeds to step S42 when the predetermined time elapses. The driving of the device 16 is stopped, and the process returns to step S32.

  FIG. 8 is a block diagram showing a fourth embodiment according to the present invention. The fourth embodiment is characterized in that an effective time zone for driving a lighting device is set and managed.

  In FIG. 8, the alarm device 10 is provided with a processor 12, a flame detection unit 14, a lighting device 16, an acoustic alarm unit 18, and a transfer unit 20, and this point is the same as the first embodiment of FIG. In addition to this, a time acquisition unit 42 is further provided.

  The time acquisition unit 42 includes a calendar IC that generates and acquires time information by the alarm device 10 itself, or receives time signal information from the outside and synchronizes the time to obtain time information such as a radio clock. Appropriate time acquisition means such as providing an IC to be generated or obtaining time information from an external device with a clock function can be used. Further, it is only necessary to provide means capable of acquiring time information necessary for whether or not lighting lighting control is possible, such as a time zone, instead of detailed time information.

  The processor 12 is provided with a time management unit 44 corresponding to the time acquisition unit 42 in addition to the fire determination unit 26 and the illumination control unit 32 as functions realized by execution of the program by the CPU. The fire determination unit 26 is provided with a flame determination unit 28 and a flicker determination unit 30. The fire determination unit 28 determines that a fire is detected when the detection signal from the ultraviolet sensor 22 exceeds a predetermined standard. The flicker determination unit 30 performs a second-stage fire determination in which a flicker frequency characteristic peculiar to a flame is obtained by frequency analysis of a detection signal from the infrared sensor 24 to determine a fire.

  The time management unit 44 sets a control effective time zone in which the illumination control unit 32 drives the illumination device 16. When the first stage fire determination result by the flame determination unit 28 of the fire determination unit 26 is obtained, the illumination control unit 32 uses the control effective time set by the time management unit 44 based on the current time acquired from the time acquisition unit 42. If it is in the belt, the lighting device 16 is driven. If the control effective time zone is not entered, the lighting device 16 is not driven.

  As a control effective time zone of the lighting device 16 set by the time management unit 44, a night time zone is set. Of course, it is also possible to set a time zone including a daytime time zone as necessary, such as when the monitoring area is always in a dark place.

  FIG. 9 is a flowchart showing a schematic example of the fire monitoring process according to the fourth embodiment of FIG. 8, which is a control process by the processor 12 of FIG. In FIG. 9, when the alarm device 10 is turned on, the processor 12 performs initialization and self-diagnosis processing in step S51. If there is no error, the detected value from the ultraviolet sensor 22 exceeds a predetermined reference in step S52. The fire judgment of the first stage is performed by whether or not.

  If it is determined in step S52 that it is equal to or greater than the predetermined reference, the process proceeds to step S53, where it is determined whether or not the current time acquired from the time acquisition unit 42 is an effective time zone for lighting control set in the time management unit 44. If it is an effective time zone, it will progress to step S54, will drive the illuminating device 16, will illuminate the monitoring area, will intimidate and deport the arson.

  If the lighting control effective time zone is not entered in step S53, the lighting device in step S54 is not driven. This is a waste of time because even if the lighting device 16 is turned on in the first-stage fire determination result in the daytime time period, the lighting device 16 does not have a threatening effect because the surroundings are bright. The lighting device 16 is not driven. However, an acoustic alarm with a small volume or an acoustic alarm for a short time may be performed.

  Subsequently, in step S55, a second-stage fire determination, which is a flicker frequency analysis, is performed from the detection signal of the infrared sensor 24. In step S56, a flame-specific flicker frequency is determined. In step S58, a fire is determined. In step S59, a fire is determined. The information is transferred and a fire alarm is issued from an external monitoring panel or sound device. If there is a fire recovery in step S60, the driving of the lighting device 16 is stopped in step S61 and the process returns to the monitoring in step S52 again. .

  If the flicker frequency specific to the flame is not determined in step S56, the elapse of a predetermined time is waited in step S57. If the lighting device is driven, the driving of the lighting device 16 is stopped in step S61. After that, the process returns to the monitoring in step S52.

  FIG. 10 is a block diagram showing a fifth embodiment of an alarm device according to the present invention. In the fifth embodiment, a light / dark sensor is used in combination. In FIG. 10, the alarm device 10 is provided with a processor 12, a flame detection unit 14, an illumination device 16, an acoustic alarm unit 18 and a transfer unit 20, and in the fifth embodiment, a light / dark sensor 46 is provided. . The light / dark sensor 46 detects the brightness of the alert area and outputs a detection signal.

  In addition to the fire determination unit 26 and the illumination control unit 32, the processor 12 is provided with a light / dark determination unit 48 corresponding to the light / dark sensor 46. The brightness determination unit 48 determines a decrease in brightness of the monitoring area from the detection signal of the brightness sensor 46.

  The illumination control unit 32 controls the lighting device 16 based on the first-stage fire determination result by the flame determination unit 28 provided in the fire determination unit 26 and the determination result by the light / dark determination unit 48. In other words, the lighting control unit 32 determines that the lighting device has a first-stage fire determination result obtained by the flame determination unit 28 of the fire determination unit 26 when the brightness determination unit 48 determines that the brightness of the monitoring area has decreased. Drive 16 to illuminate the surveillance area and intimidate the arson and move away.

  By using the light / dark sensor 46 together in this way, it is possible to avoid unnecessarily driving the illumination device 16 in a bright monitoring area.

  FIG. 11 is a flowchart showing a schematic example of the fire monitoring process according to the fifth embodiment of FIG. 10, which is a control process by the processor 12 of FIG.

  In FIG. 11, when the alarm device 10 is turned on, after the processor 12 performs initialization and self-diagnosis in step S71, if there is no error, the process proceeds to step S72, and the detection value from the ultraviolet sensor 22 exceeds a predetermined threshold value. The fire judgment of the first stage of whether or not will be.

  If the fire determination result is equal to or greater than the threshold value, the process proceeds to step S73, where it is checked whether the brightness determination unit 48 determines a decrease in brightness based on the detection signal from the brightness sensor 46 at that time, and a decrease in brightness is determined. If yes, the process proceeds to step S74, and the lighting device 16 is driven to illuminate the alert area, thereby threatening / removing the arson. In the daytime when no reduction in brightness is determined, the lighting device is skipped in step S74 because there is no threatening effect even if the lighting is turned on.

  Since the output of the light / dark sensor changes in the “bright” direction after the occurrence of the flame, the signal from the light / dark sensor is acquired in a predetermined cycle and stored in a storage unit (not shown) by taking a moving average, etc. It is sufficient to make a light / dark judgment by referring to when a fire is detected in 1 fire judgment. Alternatively, the brightness determination may be performed in advance, and the result may be stored in a storage unit and read out.

  Subsequently, in step S75, the flicker determination unit 30 performs flicker frequency analysis by fast Fourier transform or the like from the detection signal of the infrared sensor 24, and in step S76, a second-stage fire determination is performed to determine the flicker frequency characteristic unique to the flame. When the flicker frequency characteristic peculiar to the flame is determined, a fire is determined in step S78, and a fire alarm is generated by outputting a transfer signal from the transfer unit 20 to an external monitoring panel or sound device in step S79. In step S80, the restoration operation is waited for. After the driving of the lighting device is stopped in step S81, the process returns to the monitoring in step S72.

  FIG. 12 is a block diagram showing a sixth embodiment of an alarm device according to the present invention. The sixth embodiment is characterized in that the lighting device is driven in conjunction with another alarm device.

  In FIG. 12, the alarm device 10A forms an interlocking group with an alarm device 10B installed at another location, for example. In addition to the processor 12, the flame detector 14, the lighting device 16, the acoustic alarm unit 18, and the transfer unit 20, the alarm device 10A is newly provided with a wireless communication unit 50 including an antenna 52.

  The wireless communication unit 50 includes a transmission / reception circuit compliant with, for example, a 400 MHz band low power wireless station, and can transmit / receive signals to / from another alarm device 10B. The format of this transmission / reception signal includes a transmission source code, a group code, event information indicating transmission contents, and an error detection code such as a checksum set in advance in the alarm devices 10A and 10B.

  In order to configure the interlocking group, the alarm device 10A stores a plurality of alarm device IDs including other alarm devices 10B configuring the interlocking group as transmission source codes in advance as memory table information. For this reason, when the transmission source code included in the received signal received by the wireless communication unit 50 matches the transmission source code registered in advance, it is determined as a signal from another alarm device belonging to the same interlocking group, and this is processed. Will do.

  Further, instead of the transmission source code, a group code may be registered, and processing may be performed by determining a signal from another alarm device belonging to the interlocking group based on a matching match with the group code included in the received signal. .

  The fire determination unit 26 provided in the processor 12 is provided with a flame determination unit 28 and a flicker determination unit 30. When the detection signal from the ultraviolet sensor 22 exceeds a predetermined standard in the flame determination unit, a fire is determined. The second stage of fire determination is performed, and the flicker determination unit 30 performs frequency analysis on the detection signal from the infrared sensor 24 by fast Fourier transform or the like, and determines the characteristic that is the flicker frequency inherent to the flame. The fire is judged in stages.

  The illumination control unit 32 performs the first-stage fire when the fire determination signal from the infrared sensor 24 by the flame determination unit 28 exceeds a predetermined standard, that is, the first-stage fire determination result in the fire determination unit 26 of itself. When the determination result is obtained, the lighting device 16 is driven.

  In addition, when the illumination device 16 is driven, the illumination control unit 32 transmits a wireless signal that functions as an illumination drive start signal to the other alarm device 10B by the wireless communication unit 50. This radio signal is transmitted by radio by creating an event message having the transmission source code of the alarm device 10A, the group code, and the format of the transmission signal having the event content as the illumination drive start signal.

  In addition, when the wireless communication unit 50 receives a wireless signal from another alarm device 10B or the like by the wireless communication unit 50, the illumination control unit 32 is provided on condition that the transmission source code decoded from the reception signal matches the transmission source code registered in the memory table. When the event content is decoded and the lighting drive start is determined from the event content, the lighting device 16 is driven.

  Regarding the driving of the illumination device 16 by receiving the illumination drive start signal from the other alarm device 10B, the illumination device 16 is driven after a predetermined delay time has elapsed. This is because the other alarm device 10B detects the fire caused by the fire and is warned. After a certain delay time has elapsed, the alarm device 10A drives the lighting device 16a in an interlocked manner, so that the arson is moved to the next place. In anticipation of cases, the threatening effect is enhanced.

  Furthermore, the lighting control unit 32 is provided in the fire determination unit 26 after driving its own lighting device 16, and when the second stage fire determination is not obtained by the flicker determination unit 30 and the fire is not determined, An event message serving as an illumination drive stop signal is created and transmitted from the wireless communication unit 50 to the other alarm device 10B, and driving of the illumination device in the other alarm device 10B driven in conjunction is stopped.

  When the illumination control unit 32 receives the illumination drive start signal from the other alarm device 10B and drives the illuminating device 16 in an interlocked manner, and then receives the illumination drive stop signal from the other alarm device 10B, the illumination is driven in an interlocked manner. This means that the device 16 is stopped.

  At this time, the stop of the illuminating device 16 driven in conjunction with the illumination drive stop signal from the other alarm device 10B does not stop immediately upon reception of the illumination drive stop signal, but continues to hold the illumination drive for a predetermined time, The lighting device 16 is stopped.

  As a result, in the unlikely event that the arson is moving while moving from place to place, the other alarm device 10B moves the arson with the lighting drive by the first stage flame detection, and the fire is not determined. If, after that, the arson is moving to another location, for example, the place where the alarm device 10A is installed, if the lighting device 16 is stopped immediately after the illumination drive is stopped, the arson will be illuminated by the alarm device. Since the intimidating effect will be notified, the lighting device that is driven in an interlocking manner does not stop immediately, but continues to drive the lighting, so that the moving fireman approaches the warning area where the alarm device 10A is installed. Prevent things from happening.

  In order to further avoid unnecessary consumption of power due to the start of lighting driving too early, it may be necessary for the arson to move from the warning area of one alarm device to the warning area of another alarm device. Depending on the result of the first fire judgment, only the own lighting device is driven and the other alarm devices are not linked to the lighting. After the second fire judgment is made and the fire is determined, the other alarm devices are driven (interlocked). You may make it make it.

  FIG. 13 is a flowchart showing a schematic example of the fire monitoring process according to the sixth embodiment of FIG. 11, which is a control process by the processor 12 of FIG.

  In FIG. 13, when the alarm device 10A is turned on, the processor 12 performs initialization and self-diagnosis in step S91. If there is no error, the process proceeds to step S92, and whether the detection value of the ultraviolet sensor 22 exceeds a predetermined standard. If the first fire judgment is made and the result exceeds the predetermined standard, the process proceeds to step S93, where the lighting control unit 32 drives the lighting device 16 to intimidate / remove the arson. Let

  Subsequently, in step S94, an illumination drive start signal is transmitted to the other alarm device 10B, and the other alarm device 10B performs interlocking driving of the illumination device.

  Subsequently, in step S95, frequency analysis such as fast Fourier transform of the detection signal from the infrared sensor 24 by the flicker determination unit 30 is performed, and when the flicker frequency specific to the flame is determined in step S96, a fire is determined in step S98. In S99, a fire alarm signal is output by outputting a fire alarm signal from the alarm unit 20 to an external control panel, an audio device, or the like. Instead of the transmission of the transfer signal by the transfer unit 20, the fire communication signal may be transmitted from the wireless communication unit 50 to an alarm panel or an acoustic device having the same wireless communication function to cause an alarm.

  Subsequently, when the restoration operation is determined in step S100, the driving of the lighting device is stopped in step S101, and a lighting driving stop signal is transmitted from the wireless communication unit 50 to the other alarm device 10B.

  If determination of the flicker frequency of the flame cannot be obtained after driving the lighting device 16 in step S96, the elapse of a predetermined time is awaited in step S97, and the flicker frequency specific to the flame cannot be determined during that time. In this case, the process proceeds to step S101, and the driving of the illumination device 16 is stopped, and at the same time, an illumination drive stop signal is transmitted to the other alarm device 10B.

  On the other hand, if the detection value from the ultraviolet sensor 22 is less than the predetermined reference in step S92, the process proceeds to step S102 to check whether or not the illumination drive start signal is received from another alarm device, and this is received. Then, the process proceeds to step S103, and after a predetermined delay time has elapsed, the illumination device 16 is driven in an interlocked manner in step S104.

  Subsequently, in step S105, it is checked whether or not an illumination drive stop signal has been received from another alarm device. When this is received, after a predetermined time has elapsed in step S106, driving of the illumination device 16 is stopped in step S107. Will do.

  In the third embodiment of FIG. 6, the fourth embodiment of FIG. 8, the fifth embodiment of FIG. 10, and the sixth embodiment of FIG. 12, the detection value of the ultraviolet sensor 22 in the flame determination unit 28. Example of a two-stage determination of a first-stage fire determination in which is equal to or greater than a predetermined standard, followed by a second-stage fire determination that determines the flicker frequency inherent to the flame by frequency analysis of the detection signal from the infrared sensor 24 However, the third embodiment also applies to the three-stage fire determination in the first embodiment of FIG. 1 or the two-stage fire determination that combines the two infrared wavelengths and the flicker determination in the second embodiment of FIG. Embodiments of combined use of human sensors according to the sixth embodiment, illumination control according to time, combined use of light and dark sensors, and interlocking driving of illumination with other alarm devices can be applied.

  The recovery determination in the flowcharts of the embodiments shown so far may be determined by receiving a recovery instruction from the terminal of the fire transfer destination, or by receiving a recovery button on the alarm device of the present invention. Alternatively, it may be determined to be restored when it is determined that the fire condition has been resolved by performing a fire determination again after the fire is determined.

  Of course, in each embodiment, when a fire is determined and a fire is transferred, an alarm can be output from the acoustic alarm unit provided in the alarm device of the present invention.

  Moreover, although the fire determination in a plurality of stages of the fire determination unit in the present invention is a combination in which the first stage is determined by wavelength and the second stage is determined by flicker, the present invention is limited to the above embodiment. If it is a fire judgment that judges the stage of expansion from a small scale of flame due to arson to a fire step by step, an appropriate combination of fire judgment can be used, and the judgment stage is also divided into two stages. Not limited to this, it is only necessary to control the lighting at a plurality of appropriate stages and to determine or transfer a fire at an appropriate subsequent stage.

The present invention includes appropriate modifications that do not impair the object and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

10: alarm device 12: processor 14: sensor unit 16: lighting device 18: acoustic alarm unit 20: transfer unit 22: ultraviolet sensor 24: infrared sensor 24a: first infrared sensor 24b: second infrared sensor 26: fire determination unit 28: Flame determination unit
30: Flicker determination unit 32: Illumination control unit 34: Translucent window 36a: λ1 optical wavelength filter 36b: λ2 optical wavelength filter 38: Human sensor 40: Human determination unit 42: Time acquisition unit 44: Time management unit 46: Light / dark sensor 48: Light / dark determination unit 50: Wireless communication unit 52: Antenna

Claims (14)

For alarms installed outdoors or semi-outdoors to monitor fires in the surveillance area,
A flame detection unit that detects a flame and outputs a detection signal;
A fire determination unit that determines a fire by dividing into a plurality of stages from the detection signal of the flame detection unit, and determines a fire when a fire determination result of each stage satisfies a predetermined condition;
A lighting device that illuminates part or all of the monitoring area;
Among the multiple stages of fire determination determined by the fire determination unit, an illumination control unit that drives the lighting device based on the result of at least one fire determination before reaching the fire determination;
An alarm device characterized by providing.
The alarm device according to claim 1, wherein
The flame detector is
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit performs a first-stage fire determination for determining a fire based on a detection signal from the ultraviolet sensor and a second-stage fire determination for determining a fire based on a detection signal from the infrared sensor. The fire is determined based on the result of the fire determination in the second stage,
The said lighting control part drives the said illuminating device when the fire determination result of the 1st step is obtained by the said fire determination part, The alarm device characterized by the above-mentioned.
The alarm device according to claim 1, wherein
The flame detector is
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit is configured to determine whether a detection signal from the ultraviolet sensor exceeds a predetermined reference, and to determine whether a detection signal from the infrared sensor exceeds a predetermined reference. Make a fire judgment of the stage, and determine the fire based on the fire judgment result of the second stage,
The said lighting control part drives the said illuminating device when the fire determination result of the 1st step is obtained by the said fire determination part, The alarm device characterized by the above-mentioned.
The alarm device according to claim 1, wherein
The flame detector is
An ultraviolet sensor that detects the ultraviolet light emitted from the flame and outputs a detection signal;
An infrared sensor that detects infrared rays emitted from the flame and outputs detection signals;
With
The fire determination unit determines a first-stage fire determination that determines that a detection signal from the ultraviolet sensor exceeds a predetermined reference, and determines that a predetermined fluctuation frequency specific to flame is obtained from the infrared sensor. Make a fire judgment in the second stage, determine the fire based on the fire judgment result in the second stage,
The said lighting control part drives the said illuminating device when the fire determination result of the 1st step is obtained by the said fire determination part, The alarm device characterized by the above-mentioned.
The alarm device according to claim 1, wherein
The flame detector is
It has multiple infrared sensors that detect infrared rays of different wavelengths from the flame and output detection signals,
The fire determination unit is configured to determine a flame based on a correlation between detection signals of the plurality of infrared sensors, a predetermined fire-specific determination from a detection signal from at least one of the plurality of infrared sensors. The second stage fire judgment is performed to determine that the fluctuation frequency of the second stage is obtained, and the fire is determined based on the result of the second stage fire judgment.
The said lighting control part drives the said illuminating device when the fire determination result of the 1st step is obtained by the said fire determination part, The alarm device characterized by the above-mentioned.
The alarm device according to claim 1, wherein
The flame detector is
A first infrared sensor that detects an infrared ray having a predetermined wavelength corresponding to CO ₂ resonance radiation emitted from the flame and outputs a detection signal;
A second infrared sensor for detecting infrared light of a wavelength other than the predetermined wavelength corresponding to the CO ₂ resonance radiation and outputting a detection signal;
With
The fire determination unit is a first-stage fire determination in which the detection signal from the first infrared sensor exceeds a predetermined reference and the detection signal from the second infrared sensor is equal to or lower than a predetermined reference; Performing a second-stage fire determination to determine that a predetermined fluctuation frequency specific to a flame is obtained from a detection signal from the first infrared sensor, and determining a fire based on the second-stage fire determination result;
The said lighting control part drives the said illuminating device when the fire determination result of the 1st step is obtained by the said fire determination part, The alarm device characterized by the above-mentioned.
The alarm device according to claim 1, further comprising:
A human sensor that detects a person present in the monitoring area and outputs a detection signal;
A person determination unit for determining presence or intrusion of a person from a detection signal of the human sensor;
Provided,
The lighting control unit includes at least one fire determination before reaching the fire determination among a plurality of fire determinations determined by the fire determination unit when the person determination unit determines the presence or intrusion of a person. The lighting device is driven based on the result of the above.
The alarm device according to claim 1, further comprising:
A time acquisition unit for acquiring the current time;
A time management unit for setting a predetermined time zone as a control effective time zone of the lighting device;
Provided,
The lighting control unit, as a result of at least one fire determination before reaching the fire determination, among a plurality of fire determinations determined by the fire determination unit in a control effective time zone set by the time management unit. An alarm device characterized in that the lighting device is driven based on the alarm device.
The alarm device according to claim 1, further comprising:
A brightness sensor that detects the brightness of the monitoring area and outputs a detection signal;
A light / dark determination unit for determining a decrease in brightness of the monitoring area from the detection signal of the light / dark sensor;
Provided,
The lighting control unit includes at least one of a plurality of fire determinations determined by the fire determination unit before reaching the fire determination when the brightness decrease of the monitoring area is determined by the light / dark determination unit. An alarm device, wherein the lighting device is driven based on the result of two fire determinations.
The alarm device according to any one of claims 1 to 9,
The said lighting control part stops the drive of the said illuminating device, when the said fire determination part does not conclude a fire after driving the said illuminating device.
The alarm device according to claim 1, wherein
In addition, a communication unit that sends and receives signals to and from other alarm devices is provided.
When the lighting control unit starts driving the lighting device, the communication unit transmits a lighting driving start signal to another alarm device, while the communication unit receives a lighting driving start signal from another alarm device. When this happens, the alarm device is characterized by driving its own lighting device.
The alarm device according to claim 1, wherein
In addition, a communication unit that sends and receives signals to and from other alarm devices is provided.
The lighting control unit transmits a lighting drive start signal to another alarm device by the communication unit when a fire is determined by the fire determination unit, while an illumination drive start signal is transmitted from the other alarm device by the communication unit. An alarm device that, when received, drives its own lighting device.
13. The alarm device according to claim 11 or 12, wherein when the illumination control unit receives an illumination drive start signal from another alarm device, the illumination control unit drives its own illumination device after a predetermined delay time has elapsed since the signal reception. Alarm device characterized by.
  14. The alarm device according to claim 11, wherein when the illumination control unit receives an illumination drive stop signal from another alarm device, the illumination control unit continues to drive the illumination device for a predetermined period of time. An alarm device that stops after being stopped.

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