JP6846087B2 - Alarm - Google Patents

Description

The present invention relates to an alarm device that is installed in a general house or the like and is battery-powered to monitor and give an alarm for an abnormality such as a fire.

Conventionally, alarm devices that detect and warn of abnormalities such as fires and gas leaks in houses have become widespread. Of these, residential fire alarms are called residential alarms.

In such a residential alarm, a sensor unit and an alarm unit are provided in the residential alarm, and when a fire is detected, a fire alarm is issued, and the fire alarm can be monitored and alarmed by itself. Therefore, it is easy to install and inexpensive, and it has become widespread due to the mandatory installation in general houses.

In addition, by communicating with each other between multiple smoke detectors, when a fire alarm sound is output by any of the smoke detectors, the fire alarm sound is output in conjunction with other smoke detectors. The wireless interlocking type residential alarm system has also been put into practical use and has become widespread.

Such a residential police device that detects a fire by smoke or heat has a position restriction when it is installed on a wall surface or a ceiling, and the restriction is conventionally described in the instruction manual.

As a restriction, for example, when installing on a wall surface, it is required to maintain a distance of 15 cm to 50 cm from the ceiling surface, and when installing on a ceiling surface, it is required to install at least 60 cm away from the wall surface as a usage condition. are doing. It also requires that it be not installed near air conditioners, lighting fixtures or gas ranges.

However, when a resident tries to install a smoke alarm, the installation work may be performed without checking the instruction manual, and if the alarm device is installed in an inappropriate position, the fire detection performance will be improved. There is a problem that it may not be secured.

In order to solve this problem, the Smoke Detector is designed to output construction guidance that explains the installation standards when the battery is installed in the Smoke Detector, the power is turned on, and the prescribed operation is performed in the operation unit. It has been proposed (Patent Document 1), and the installer can know the installation standard without reading the instruction manual, and there is no possibility that the alarm device will be installed in the wrong position.

In addition, this Smoke Detector measures environmental factors with a sensor by a predetermined operation, and outputs construction guidance that notifies the quality of the environmental factors at the installation position. As a result, if the Smoke Detector is installed in an inappropriate position, the quality of the installation position can be checked after installation, and if it is inappropriate, it can be reattached to the appropriate position.

Japanese Unexamined Patent Publication No. 2010-033236 Japanese Unexamined Patent Publication No. 2004-54356 Japanese Unexamined Patent Publication No. 2005-44317 Japanese Unexamined Patent Publication No. 2007-11828

However, even if the Smoke Detector is installed and used in an appropriate position according to the installation instructions, the Smoke Detector may operate due to factors other than fire and output a non-fire alarm, and the resident is not a fire. After confirming that, the alarm will be stopped, but the cause of the non-fire alarm is often unknown, and we have no choice but to continue using it with anxiety without knowing the cause. In cases where it occurs frequently, there is a risk that initial fire extinguishing and evacuation will be hindered due to the assumption that it is a non-fire alarm even when a fire alarm is output in an actual fire. In addition, due to changes in external factors, an improper installation environment may result in malfunction and lead to fire misreporting.

According to the present invention, it is possible to maintain the reliability of the fire alarm by notifying the cause of the non-fire alarm that occurred while installing and using it at an appropriate position, and the surrounding environment becomes an inappropriate installation environment. The purpose is to provide an alarm that detects and outputs a warning.

(Monitoring of ambient environment abnormalities)
The present invention
An abnormality sensor unit that detects an abnormality in the monitoring area and outputs a detection signal,
A notification unit that notifies a predetermined event including an alarm,
An abnormality monitoring unit that outputs an abnormality alarm by the alarm sound and alarm display of the notification unit when an abnormality is detected based on the detection signal of the abnormality sensor unit.
In the alarm equipped with
An environmental abnormality detection sensor that detects abnormalities in the surrounding environment of the alarm, and
When the surrounding environment detected by the environmental abnormality detection sensor unit is out of the operating range, it is retained as an operation obstruction factor, and the operation obstruction factor monitoring unit that outputs the operation obstruction factor in cooperation with the abnormality alarm by the abnormality monitoring unit.
Is characterized by the provision of.

(Temperature sensor)
The environmental abnormality detection sensor unit is equipped with a temperature sensor that detects the ambient temperature of the alarm, and the operation obstruction personnel monitoring unit operates when the temperature detected by the temperature sensor exceeds the upper limit temperature of the predetermined operating temperature range. It is retained as a disturbing factor and output by voice message in cooperation with the abnormality alarm.

(Noise sensor)
The environmental abnormality detection sensor unit is equipped with a noise sensor that detects the electrical noise received by the alarm.
When the noise level detected by the noise sensor becomes equal to or higher than a predetermined threshold level, the operation obstruction personnel monitoring unit holds it as an operation obstruction factor and outputs it by a voice message in cooperation with an abnormality alarm.

(Distance sensor)
The environmental abnormality detection sensor unit includes a distance sensor that detects the distance to an object existing around the alarm.
The operation obstruction factor monitoring unit outputs an alarm indicating the operation obstruction factor when the distance detected by the distance sensor becomes equal to or less than a predetermined threshold distance.

(Wind speed sensor)
The environmental abnormality detection sensor unit is equipped with a wind speed sensor that detects the wind speed received by the alarm.
The operation obstruction factor monitoring unit outputs an alarm indicating the operation obstruction factor when the wind speed detected by the wind speed sensor becomes equal to or higher than a predetermined threshold value.

(Judgment timing of installation environment)
The operation obstruction factor monitoring unit operates the environment abnormality detection sensor unit at predetermined intervals and when a predetermined operation is detected, and determines whether or not an operation obstruction factor has occurred based on the detection result.

(Effect of an alarm that monitors the factors that interfere with operation)
The present invention has an abnormality sensor unit that detects an abnormality in a monitoring area and outputs a detection signal, a notification unit that notifies a predetermined event including an alarm, and a case where an abnormality is detected based on a detection signal of the abnormality sensor unit. In an alarm device equipped with an abnormality monitoring unit that outputs an abnormality alarm by the alarm sound of the notification unit and an alarm display, an environmental abnormality detection sensor unit that detects an abnormality in the surrounding environment of the alarm unit and an environmental abnormality detection sensor unit. When the surrounding environment detected by is out of the operating range, it is retained as an operation obstruction factor, and an operation obstruction factor monitoring unit that outputs the operation obstruction factor in cooperation with the abnormality alarm by the abnormality monitoring unit is provided. If a non-fire alarm is issued due to a cause other than a fire while the product is installed and used in an appropriate position, confirm that the resident is not a fire and stop the alarm. When this is done, for example, a voice message outputs the operation obstruction factor held at that time, so that the resident knows the operation obstruction factor that becomes a non-fire alarm, and if it is a transient operation obstruction factor, It is possible to maintain reliability by convincing it and knowing that the alarm itself is not the cause, and if it is a resolvable operational obstruction factor, it is possible to suppress the recurrence of non-fire alarms by taking necessary measures. It becomes.

(Effect of temperature sensor)
In addition, the environmental abnormality detection sensor unit is equipped with a temperature sensor that detects the ambient temperature of the alarm, and the operation obstruction personnel monitoring unit is when the temperature detected by the temperature sensor is equal to or higher than the upper limit temperature of the predetermined operating temperature range. Because it is retained as an operation obstruction factor and output by voice message in cooperation with the abnormality alarm, it is known that the operation obstruction factor that becomes a non-fire alarm is, for example, an abnormally high temperature in the room, and it is not due to the subsequent temperature situation Since the possibility of a fire alarm can be estimated, there is no need to worry, and when a high temperature warning is issued, it is possible to take measures such as preventing the room temperature from rising too high.

(Effect of noise sensor)
In addition, the environmental abnormality detection sensor unit is equipped with a noise sensor that detects the electrical noise received by the alarm, and the operation obstruction personnel monitoring unit is when the noise level detected by the noise sensor exceeds a predetermined threshold level. Since it is retained as an operation obstruction factor and output by voice message in cooperation with an abnormality alarm, it is known that the operation obstruction factor that becomes a non-fire alarm is due to electrical noise, and it becomes a new noise source near the alarm. When electrical equipment is placed, it is possible to take measures such as moving the electrical equipment away from the alarm, and if there is a thunderstorm when a non-fire alarm is issued, lightning noise will interfere with the operation. Even if the cause can be presumed to be the cause and the cause of the non-fire alarm is electrical noise that cannot be recognized by the five senses, necessary measures and attitudes can be taken without worrying about it.

(Effect of distance sensor)
In addition, the environmental abnormality detection sensor unit includes a distance sensor that detects the distance to an object existing around the alarm, and the operation obstruction factor monitoring unit has a distance detected by the distance sensor that is equal to or less than a predetermined threshold distance. In this case, an alarm indicating the factor that interferes with the operation is output. Therefore, if an alarm indicating the factor that interferes with the operation is output when furniture or home appliances are installed, it is known that the alarm device is too close to the alarm. It is possible to remove the factors that interfere with the operation by arranging it in an appropriate position where the alarm does not appear.

(Effect of wind speed sensor)
Further, the environmental abnormality detection sensor unit is provided with a wind speed sensor that detects the wind speed received by the alarm, and the operation obstruction factor monitoring unit is an operation obstruction factor when the wind speed detected by the wind speed sensor becomes a predetermined threshold wind speed abnormality. Because the alarm indicating the above is output, the installation environment is inappropriate for the resident because the alarm indicating the cause of operation obstruction is output by installing a fan on the wall surface or receiving the wind when the air conditioner is operated. It is possible to eliminate the factors that interfere with the operation by changing the installation location of the fan and adjusting the wind direction of the air conditioner.

(Effect of judgment timing of installation environment)
In addition, the operation obstruction factor monitoring unit operates the environment abnormality detection sensor unit at predetermined intervals and when a predetermined operation is detected, and determines whether or not an operation obstruction factor has occurred based on the detection result. Therefore, for example, the environmental abnormality detection sensor unit can be operated at a cycle of once an hour to monitor changes in the installation environment, and changes in the installation environment can be monitored and operation obstructed without the need for resident operation. Enables alarms that indicate factors. In addition, when furniture or home appliances are newly installed, whether or not the environmental abnormality detection sensor unit is activated by pressing and holding the alarm stop switch provided on the alarm device to interfere with the operation. Can be confirmed.

Explanatory drawing showing the appearance of the Smoke Detector A block diagram showing a functional configuration according to the first embodiment of the Smoke Detector shown in FIG. Flow chart showing the control operation in the Smoke Detector in FIG. A block diagram showing a functional configuration according to the second embodiment of the Smoke Detector shown in FIG. Flow chart showing the control operation in the Smoke Detector of FIG. A flowchart showing the details of the installation environment monitoring process in step S1 of FIG. A block diagram showing the functional configuration of the wirelessly interlocking Smoke Detector according to the third embodiment. A time chart showing the temporal changes in the temperature around the equipment and the temperature inside the smoke detector.

[Appearance of Smoke Detector]
FIG. 1 is an explanatory view showing the appearance of a smoke detector, FIG. 1 (A) shows a front view, and FIG. 1 (B) shows a side view.

As shown in FIG. 1, the housing of the Smoke Detector 10 of the present embodiment is composed of a cover 12 and a main body 14. The cover 12 is provided with a protrusion in the center, a plurality of smoke inlets are opened around the cover 12, and a smoke detection unit 16 is arranged inside the cover 12 to detect a fire when the smoke from the fire reaches a predetermined concentration. I am trying to do it.

An acoustic hole 18 is provided on the lower left side of the smoke detection unit 16 provided on the cover 12, and an acoustic output device such as a buzzer or a speaker is built in behind the acoustic hole 18 so that an alarm sound or a voice message can be output. An alarm stop switch 20 is provided below the smoke detection unit 16.

The alarm stop switch 20 is composed of a switch cover formed of a translucent member and a tact switch (not shown) arranged inside the switch cover. An LED 22 that displays an alarm is arranged near the tact switch inside the switch cover as shown by a dotted line. When the LED 22 lights up, blinks, or blinks, the LED 22 passes through the switch cover portion of the alarm stop switch 20. The operating state of is made visible from the outside.

The alarm stop switch 20 functions as an alarm stop switch that stops the alarm when operated during the fire alarm of the residential alarm system 10. Further, when the alarm stop switch 20 is operated in the normal state of the Smoke Detector 10, it functions as an inspection switch that executes a predetermined inspection operation and outputs an inspection result by a voice message.

Further, in the present embodiment, a fire alarm is output, the resident looks around the house to confirm non-fire, operates the alarm stop switch 20 to stop the alarm, and then the LED 22 emits the alarm at a predetermined cycle. When the alarm stop switch 20 is operated when it is lit and an alarm sound such as "beep" is output, it functions as an operation obstruction factor notification switch that outputs a voice message indicating an operation obstruction factor.

Further, a mounting hook 15 having an insertion hole in a substantially central portion is provided on the upper part of the back side of the main body 14, and a screw or the like is screwed into the wall surface or the like of the room to be installed, and the screw is passed through the insertion hole of the mounting hook 15. , The Smoke Detector 10 can be fixedly installed on a wall surface or the like in a so-called wall-mounted manner.

[First Embodiment of Smoke Detector]
(Functional configuration of Smoke Detector)
FIG. 2 is a block diagram showing a first embodiment of the Smoke Detector shown in FIG. 1 by a functional configuration. As shown in FIG. 2, the housing police 10 includes a processor 24 known as a one-chip CPU, a smoke detection unit 16 that functions as an abnormality sensor unit for the processor 24, and an alarm stop switch 20 that functions as an operation unit. An LED 22 including a drive circuit that functions as a display unit, a speaker 26 that includes a drive circuit that functions as an acoustic notification unit, and an environmental abnormality detection sensor unit 28 are provided, and power is supplied to each unit to operate by using a battery (not shown). ..

The environmental abnormality detection sensor unit 28 is a sensor unit that detects a non-fire phenomenon that causes a non-fire report, and in the present embodiment, a temperature sensor 30 and a noise sensor 32 are provided.

The temperature sensor 30 outputs a temperature detection signal corresponding to the environmental temperature by a temperature detection element such as a thermistor or a voltage between the base and emitter of a transistor. When a temperature detection element such as a thermistor that detects the temperature due to a fire is provided instead of the smoke detection unit 16 that functions as an abnormality sensor unit, the difference in temperature change between the temperature detection element and the temperature sensor 30 is used. Detect a fire.

For example, as shown in FIG. 8A, when the temperature rise of the temperature Ta in the peripheral portion of the device measured by the temperature sensor 30 is fast and the temperature rise speed of the temperature Tb inside the housing guard measured by the temperature detection element is slow. Detects as a fire due to rapid temperature changes. On the other hand, as shown in FIG. 8B, when there is no significant difference between the temperature Ta around the device and the temperature Tb inside the Smoke Detector, it is detected as an environmental abnormality because it is a gradual temperature change. ..

The noise sensor 32 detects the electrical noise received by the Smoke Detector 10 and outputs a noise detection signal. The electrical noise received by the Smoke Detector 10 includes home appliances such as lighting fixtures, air conditioners, microwave ovens, and refrigerators installed in houses, and the pulse noise associated with turning on and off these home appliances is generated. receive. In addition, the Smoke Detector 10 receives switching noise of a predetermined frequency from home appliances using an inverter. In addition, when there is a thunderstorm, the Smoke Detector 10 receives lightning noise.

These electrical noises are detected by the noise sensor 32, and a noise detection signal is output. The noise sensor 32 includes a noise detection element such as an antenna or a coil, and a noise detection circuit that outputs a noise detection signal corresponding to the noise received by the noise detection element.

Since the noise applied to the Smoke Detector 10 is often pulse-like noise, for example, a peak level detection circuit that maintains and outputs the peak level of noise is used as the noise detection circuit.

Further, a one-shot pulse circuit that outputs a pulse signal having a predetermined time width with noise exceeding a predetermined threshold level as a trigger input may be used. For the pulse signal from this one-shot pulse circuit, the degree of noise generation can be determined, for example, by counting the number of pulses per unit time.

The processor 24 is provided with a CPU 34, and a control logic 38, a ROM 40, a RAM 42, an AD conversion port 44, 52, 54, an input port 46, an output port 48, and an audio output port 50 are connected to a bus 36 from the CPU 34. There is. The control logic 38 realizes various hardware functions such as bus control associated with the control process of the CPU 34.

A smoke detector 16 is connected to the AD conversion port 44, a temperature sensor 30 is connected to the AD conversion port 52, a noise sensor 32 is connected to the AD conversion port 54, and an alarm stop switch 20 is connected to the input port 46. It is connected, the LED 22 is connected to the output port 48, and the speaker 26 is connected to the audio output port 50.

The CPU 34 is provided with the functions of the fire monitoring unit 56 and the operation obstruction factor monitoring unit 58 as functions realized by executing the program.

(Fire monitoring function)
When a fire is detected from the smoke detection signal from the smoke detection unit 16, the fire monitoring unit 56 outputs an alarm sound indicating a fire from the speaker 26 and controls the LED 22 to drive an alarm display.

Specifically, the fire monitoring unit 56 compares the smoke detection signal of the smoke detection unit 16 with a predetermined threshold value, detects a fire when the threshold value is exceeded, and from the speaker 26, for example, "Woo fire is a fire." Is repeatedly output, and the LED 22 is turned on to control an alarm display.

Further, when the fire monitoring unit 56 detects the operation of the alarm stop switch 20 during the output of the fire alarm, the fire monitoring unit 56 stops (turns off) the output of the fire alarm by the voice message output from the speaker 26 and the alarm display output from the LED 22. ) Is controlled.

Further, when the fire monitoring unit 56 detects the operation of the alarm stop switch 20 in the normal state, the fire monitoring unit 56 executes a predetermined internal inspection and controls to output the inspection result from the speaker 26. If the inspection result is normal, an inspection message including an alarm message such as "normal" is output, and if a failure is detected, an inspection message such as "pit failure" is output. The contents to be inspected in the inspection process include the presence / absence of a smoke detection unit 16 (sensor) failure, the presence / absence of a circuit failure, the presence / absence of a sensitivity abnormality, and the presence / absence of other failures.

(Monitoring function for factors that interfere with operation)
The operation obstruction factor monitoring unit 58 holds as an operation obstruction factor when the non-fire phenomenon detected by the temperature sensor 30 or the noise sensor 32 of the environmental abnormality detection sensor unit 28 exceeds a predetermined threshold value, and the fire monitoring unit 56 fires. In cooperation with the alarm, the speaker 26 controls to output the operation obstruction factor held at that time by a voice message.

The operation obstruction factor monitoring unit 58 reads the detected temperature from the temperature detection signal of the temperature sensor 30 at a predetermined sampling cycle by the AD conversion port 52, and the operating temperature range of the housing guard 10 is 0 ° C to 40 ° C. Therefore, for example, when the detection temperature reaches 40 ° C. or higher, which is the upper limit temperature of the operating temperature range, the abnormally high temperature is maintained as an operation obstruction factor, and when the operation of the alarm stop switch 20 linked to the fire alarm is detected, Control is performed to output by a voice message indicating that the cause of operation obstruction is an abnormally high temperature in the room.

Here, the operation of the alarm stop switch 20 linked to the fire alarm means an operation according to the following operation procedure. When a fire alarm is output from the housing alarm 10, the resident examines the inside of the house, and when it is confirmed that there is no fire, the alarm stop switch 20 is operated to stop the fire alarm.

Here, when the operation obstruction factor is a high temperature abnormality, the operation obstruction factor monitoring unit 58 determines and holds the high temperature abnormality as an operation obstruction factor before the non-fire report, and when the alarm stop operation is performed, the alarm stop operation is performed. Control is performed so that the LED 22 is turned on at a cycle of, for example, about 10 seconds, and an alarm sound such as "beep" is output from the speaker 26 to output a warning alert. When the operation of the alarm stop switch 20 is detected during the output of the warning alert, the operation obstruction factor monitoring unit 58 controls to output a voice message indicating that the operation obstruction factor is at an abnormally high temperature in the room. ..

From such a voice message of the Smoke Detector 10, the resident knows that the cause of the operation obstruction was an abnormal temperature in the room, so that he / she does not become unnecessarily anxious, and a high temperature warning is issued as weather information. In such a case, it is possible to take measures such as preventing the room temperature from rising too high.

Further, the operation obstruction factor monitoring unit 58 holds a noise abnormality as an operation obstruction factor when the noise level read from the AD conversion port 54 at a predetermined sampling cycle becomes equal to or higher than a predetermined threshold level, and in the case of a high temperature abnormality. Similarly, the speaker 26 is controlled to output a voice message indicating that the noise abnormality is an operation obstruction factor in cooperation with the fire alarm.

Therefore, the resident knows that the cause of the operation obstruction is electrical noise by operating the alarm stop switch 20 when the warning alarm is output after stopping the fire alarm by the non-fire alarm, and the resident police officer 10 If an electric device that becomes a noise source is newly placed near the, it is possible to take measures such as moving the electric device away from the Smoke Detector 10. In addition, if there is a thunderstorm when a non-fire report is issued, it can be estimated that the noise caused by the lightning strike is the cause of the operation interruption, and the cause of the operation interference is the electrical noise that cannot be detected by humans. Even if there is, it is possible to take necessary measures and prepare for it without worrying about it.

(Control operation of Smoke detector)
FIG. 3 is a flowchart showing the control operation in the Smoke Detector of FIG. 2, and the control operation is performed by the fire monitoring unit 56 and the operation obstruction factor monitoring unit 58 provided in the CPU 34 of FIG.

As shown in FIG. 3, when the operation is started by receiving the power supply from the battery of the Smoke Detector 10, initialization and self-diagnosis are executed in step S1, and if there is no abnormality, the process proceeds to step S2, and the smoke detector 16. Each detection signal of the temperature sensor 30 and the noise sensor 32 is read by AD conversion at predetermined sampling cycles, and the sensor detection signal reading process for temporarily storing the detection value in the memory is performed.

Subsequently, the process proceeds to step S3, and it is determined whether or not the detection temperature of the temperature sensor 30 and the detection noise level of the noise sensor 32 exceed a predetermined threshold value. If the threshold value is exceeded, a high temperature abnormality or noise abnormality is operated in step S4. Hold in memory as a disturbing factor.

Subsequently, the process proceeds to step S5, and if the detected smoke concentration of the smoke detection unit 16 is equal to or higher than the fire determination threshold value, fire detection is determined, and the process proceeds to step S6 to turn on the LED 22 and fire due to a fire alarm message from the speaker 26. Output an alarm.

Subsequently, when the operation of the alarm stop switch 20 is determined in step S7, the process proceeds to step S8 to stop the fire alarm. Subsequently, when the holding of the operation obstruction factor is determined in step S9 and the operation of the alarm stop switch 20 is further determined in step S10, the process proceeds to step S11 to output a voice message indicating the operation obstruction factor. Subsequently, the process proceeds to step S12, and the non-fire alarm and its operation obstruction factor are stored in the memory as history information, and the manufacturer or the like can read the history information as necessary and use it for the cause analysis of the operation obstruction.

[Second Embodiment of Smoke Detector]
(Functional configuration of Smoke Detector)
FIG. 4 is a block diagram showing a second embodiment of the Smoke Detector shown in FIG. 1 by a functional configuration. As shown in FIG. 4, in the present embodiment, as in the first embodiment of FIG. 2, the Smoke Detector 10 includes a processor 24 known as a one-chip CPU, and smoke detection is performed on the processor 24. A unit 16, an alarm stop switch 20, an LED 22, a speaker 26, and an environmental abnormality detection sensor unit 28 are provided, and power is supplied to each unit by a battery (not shown) to operate the unit. In this embodiment, a distance sensor 62 and a wind speed sensor 64 are provided as functions for detecting the installation environment of the device 10.

(Monitoring the installation environment with a distance sensor)
As the distance sensor 62, for example, an ultrasonic sensor is used, and the distance to an object existing around the Smoke Detector 10 is detected. The ultrasonic sensor used as the distance sensor 62 transmits ultrasonic waves toward an object by a transmitter, receives the reflected waves by a receiver, and is a target based on the ultrasonic propagation time from transmission to reception. Detect the distance to an object.

The distance sensor 62 using the ultrasonic sensor is arranged at least below the cover 12 of the smoke detector 10 shown in FIG. 1, and detects the distance to the object existing below the smoke detector 10. Further, a plurality of distance sensors 62 may be provided so that the distances to the objects existing in the upward direction and the left-right direction of the Smoke Detector 10 can be detected.

When the operation obstruction factor monitoring unit 28 detects a special operation of the alarm stop switch 20, for example, a long press operation at predetermined intervals or in a normal monitoring state, the operation obstruction factor monitoring unit 28 operates the distance sensor 62 to convert the detected distance into the AD conversion port 66. When the detected distance is less than or equal to a predetermined threshold distance for ensuring an appropriate installation environment, an alarm indicating an operation obstruction factor is output.

The alarm output indicating the operation obstruction factor by the operation obstruction factor monitoring unit 28 is such that the LED 22 is turned on at a cycle of 10 seconds and an alarm sound such as "beep" is output from the speaker 26, and the alarm stop switch 20 is operated in this alarm state. Is detected, the speaker 26 controls to output a voice message indicating that an object is placed near the Smoke Detector 10.

Therefore, if a resident installs a tall bookshelf or the like near the Smoke Detector 10 during use after installing the Smoke Detector 10 in an appropriate position according to the installation manual, the Smoke Detector 10 interferes with the operation. An alarm indicating the cause is output, which allows the resident to know that the installation environment is inappropriate, and it is possible to remove the factor that interferes with the operation by reviewing the installation location of the bookshelf.

(Monitoring the installation environment with a wind speed sensor)
The wind speed sensor 64 provided in the environmental abnormality detection sensor unit 28 detects the wind speed received by the Smoke Detector 10 and outputs a wind speed detection signal. The wind speed sensor 64 of the present embodiment uses, for example, a wind speed probe having a height of about several millimeters in which a semiconductor germanium single crystal is enclosed in a metal ball or a metal tube.

As this wind speed probe, one having horizontal omnidirectional detection characteristics is used, for example, at a predetermined position of the cover 12 of the Smoke Detector 10 shown in FIG. 1, for example, the upper part of the cover that does not interfere with the mounting by the mounting hook 15. By arranging it so as to project to the position, it is possible to detect and output the wind speed of the airflow coming toward the Smoke Detector 10.

The operation obstruction factor monitoring unit 28 operates the wind speed sensor 64 to measure the detected wind speed from the AD conversion port 68 at predetermined intervals or when a special operation of the alarm stop switch 20, for example, a long press operation, is detected in a normal state. When the read and detected wind speed exceeds a predetermined threshold wind speed required to secure an appropriate installation environment, an alarm indicating an operation obstruction factor is output.

As for the output of the alarm indicating the operation obstruction factor by the operation obstruction factor monitoring unit 70, as in the case of the distance sensor 62, the LED 22 is turned on at a cycle of, for example, 10 seconds, and the speaker 26 outputs an alarm sound such as "beep", and this alarm is output. When the operation of the alarm stop switch 20 is detected in the state, the speaker 26 controls to output a voice message indicating that the housing guard 10 is receiving a strong wind.

For this reason, if the wind blown from the air conditioner or the wind from the electric fan hits the smoke detector 10 strongly during use after installing the smoke detector 10 in an appropriate position according to the installation instructions, the smoke detector 10 is used. An alarm indicating the cause of the operation obstruction is output from No. 10, and the resident knows that the installation environment is inappropriate, and the operation is obstructed by adjusting the wind direction of the air conditioner or changing the installation location of the fan. It is possible to remove the factors.

(Control operation of Smoke detector)
FIG. 5 is a flowchart showing the control operation in the Smoke Detector of FIG. 4, and FIG. 6 is a flowchart showing the details of the installation environment monitoring process in step S22 of FIG.

Step S21 shown in FIG. 5 is the same as step S1 in FIG. 3, and the processes of steps S23 to S33 shown in FIG. 5 are the same as the processes of steps S2 to S12 of FIG. As for the control operation of the device, following step S21, the operation obstruction factor monitoring process based on the installation environment in step S22 is newly added.

As shown in FIG. 6, the operation interference monitoring process based on the installation environment in step S22 of FIG. 5 proceeds to step S43 when the monitoring timing of the installation environment abnormality having a predetermined cycle, for example, a 1-minute cycle is determined in step S41, and proceeds to the environment. The distance sensor 62 and the wind speed sensor 64 provided in the abnormality detection sensor unit 28 are sequentially operated to read the detected distance and the detected wind speed.

If the monitoring timing is not set in step S41, the process proceeds to step S42, and when the long press operation of the alarm stop switch 20 is determined, the process proceeds to step S43. Similarly, the distance sensor 62 and the wind speed sensor 64 provided in the environmental abnormality detection sensor unit 28 proceed. Are sequentially operated to read the detected distance and the detected wind speed. As a result, when the resident wants to know the suitability of the installation environment of the smoke detector 10, he / she may press and hold the alarm stop switch 20.

Subsequently, the process proceeds to step S44, and when the detection distance is less than or equal to the threshold distance, or when the detected wind speed is equal to or more than the threshold wind speed, the cause of the operation obstruction is determined and the process proceeds to step S45, and the LED 22 and the speaker 26 are operated to cope with the installation environment. The operation obstruction factor alarm is output.

Subsequently, when the operation of the alarm stop switch 20 is detected in step S46, the process proceeds to step S47, indicating that an object exists near the smoke detector 10 or a strong wind hits the smoke detector 10 as an operation obstruction factor. A voice message indicating that effect is output from the speaker 26, and the process returns to step S23 in FIG.

[Third Embodiment of Smoke Detector]
FIG. 7 is a block diagram showing a functional configuration according to a third embodiment of a smoke detector that is wirelessly interlocked.

As shown in FIG. 7, in the present embodiment, as in the second embodiment of FIG. 4, the Smoke Detector 10 includes a processor 24 known as a one-chip CPU, and smoke detection is performed on the processor 24. A unit 16, an alarm stop switch 20, an LED 22, a speaker 26, and an environmental abnormality detection sensor unit 28 are provided, and power is supplied to each unit by a battery (not shown) to operate the unit. Correspondingly to this, the fire monitoring unit 56 of the processor 24 has an added function of performing interlocking alarm control with other wireless interlocking type residential guards.

The communication unit 72 transmits and receives an interlocking signal such as a fire with another Smoke detector according to a predetermined communication protocol. In the case of Japan, this communication protocol is, for example, STD-30 (radio equipment standard for low power security system radio stations) known as a standard for specific low power radio stations in the 400 MHz band or specific small for 900 MHz band. It conforms to STD-T67 (standard of radio equipment for specified low power radio station telemeter, telecontrol and data transmission) known as a standard of power radio station.

The fire alarm control by the fire monitoring unit 56 provided in the processor 24 is as follows. The fire monitoring unit 56 reads the smoke concentration detection signal output from the smoke detection unit 16 from the AD conversion port 44, detects a fire when it exceeds a predetermined threshold value, and controls to output a fire alarm indicating the interlocking source. ..

As a fire alarm in this case, the fire monitoring unit 56 repeatedly outputs an alarm sound indicating the interlocking source, for example, "Woo Woo fire alarm has been activated" from the speaker 26, and lights the LED 22, for example. An alarm display indicating the interlocking source is displayed.

When the fire alarm is output, the fire monitoring unit 56 generates a fire interlocking signal according to a predetermined communication protocol, instructs the communication unit 72, and controls to transmit the fire interlocking signal to another residential alarm system. , The other fire alarm that received the fire interlocking signal outputs a fire alarm indicating the interlocking destination.

As a fire alarm indicating the interlocking destination in this case, the fire monitoring unit 56 repeatedly outputs an alarm sound indicating the interlocking destination from the speaker 26, for example, "Woo, another fire alarm has been activated. Please check." For example, the LED 22 is blinked to display an alarm indicating the interlocking destination.

In addition, the fire monitoring unit 56 also performs interlocking control with other housing police for the stop control of the fire alarm and the recovery control of the fire.

The Smoke Detector 10 of the second embodiment of FIG. 2 is also provided with a communication unit 72 to which the antenna 74 is connected, and the fire monitoring unit 56 of the processor 24 is interlocked alarm control with the wireless interlocking Smoke Detector. You may add the function to perform.

[Modification of the present invention]
The above embodiment takes as an example a residential alarm that detects a fire and gives an alarm, but it can also be applied to various alarms such as a gas leak alarm, a CO alarm, and a security alarm.

Further, the operation unit shown as the alarm stop switch in the above embodiment does not necessarily have to be a switch, and any means or method such as one for inputting instructions by communication from the outside using a remote controller or the like can be used. It may be applied.

Further, the flowchart in the above embodiment describes a schematic example of the processing, and the order of the processing is not limited to this. In addition, a delay time can be provided for each process or between processes as necessary, and other determinations can be inserted.

Further, the above embodiment can be applied not only to residential use but also to alarm devices for various purposes such as buildings and offices.

Further, the above embodiment takes as an example the case where the sensor unit, another processing unit, and the control unit are integrally provided in the alarm device, but as another embodiment, the sensor unit, the other processing unit, and the control unit are separated. It may be a body alarm.

Further, the present invention is not limited to the above-described embodiment, includes appropriate modifications that do not impair its purpose and advantages, and is not further limited by the numerical values shown in the above-described embodiment.

10: Smoke detector 12: Cover 14: Main body 15: Mounting hook 16: Smoke detector 18: Acoustic hole 20: Alarm stop switch 22: LED
24: Processor 26: Speaker 28: Environmental abnormality detection sensor unit 30: Temperature sensor 32: Noise sensor 34: CPU
36: Bus 38: Control logic 40: ROM
42: RAM
44, 52, 54, 66, 68: AD conversion port 46: Input port 48, 50: Output port 58: Operation obstruction factor monitoring unit 62: Distance sensor 64: Wind speed sensor 72: Communication unit

Claims (7)

An abnormality sensor unit that detects an abnormality in the monitoring area and outputs a detection signal,
A notification unit that notifies a predetermined event including an alarm,
An abnormality monitoring unit that outputs an abnormality alarm by the alarm sound and alarm display of the notification unit when an abnormality is detected based on the detection signal of the abnormality sensor unit.
In the alarm equipped with
An environmental abnormality detection sensor that detects abnormalities in the surrounding environment of the alarm, and
When the surrounding environment detected by the environmental abnormality detection sensor unit is out of the operating range, the operation obstruction factor monitoring unit is retained as an operation obstruction factor, and the operation obstruction factor is output in cooperation with the abnormality alarm by the abnormality monitoring unit.
An alarm that is characterized by the provision of.
In the alarm device according to claim 1,
The environmental abnormality detection sensor unit includes a temperature sensor that detects the ambient temperature of the alarm.
When the temperature detected by the temperature sensor becomes equal to or higher than the upper limit temperature of the predetermined operating temperature range, the operation obstruction factor monitoring unit holds the operation obstruction factor as the operation obstruction factor and outputs it by a voice message in cooperation with the abnormality alarm. An alarm that is characterized by letting it go.
In the alarm device according to claim 1,
The environmental abnormality detection sensor unit includes a noise sensor that detects the electrical noise received by the alarm.
When the noise level detected by the noise sensor becomes equal to or higher than a predetermined threshold level, the operation obstruction factor monitoring unit holds it as the operation obstruction factor and outputs it by a voice message in cooperation with the abnormality alarm. Characteristic alarm.
In the alarm device according to claim 1,
The environmental abnormality detection sensor unit includes a distance sensor that detects a distance from an object existing around the alarm.
The operation obstruction factor monitoring unit is an alarm device that outputs an alarm indicating the operation obstruction factor when the distance detected by the distance sensor is equal to or less than a predetermined threshold distance.
In the alarm device according to claim 4,
The distance sensor detects at least the distance to an object underneath the alarm.
The motion obstruction factor monitoring unit is characterized in that when the distance to the lower object detected by the distance sensor becomes equal to or less than a predetermined threshold distance, an alarm indicating the motion obstruction factor is output. Alarm.
In the alarm device according to claim 1,
The environmental abnormality detection sensor unit includes a wind speed sensor that detects the wind speed received by the alarm.
The operation obstruction factor monitoring unit is an alarm device that outputs an alarm indicating the operation obstruction factor when the wind speed detected by the wind speed sensor becomes equal to or higher than a predetermined threshold value.
In the alarm device according to claim 1, the operation obstruction factor monitoring unit operates the environmental abnormality detection sensor at predetermined intervals and when a predetermined operation is detected, and based on the detection result, the operation obstruction. An alarm that determines whether or not a factor has occurred.

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