JP2010182173A - Alarm - Google Patents

Abstract

An alarm device (fire alarm device) capable of confirming whether or not an alarm device functions normally without causing a user to take trouble.
A fire alarm device 4 for detecting a fire in a monitoring area and outputting a fire alarm, a test unit (microcomputer) for performing internal circuit tests (thermistor 20 disconnection monitoring test and power supply 6 voltage drop monitoring test). 12, a voltage monitoring circuit 19), and an illumination on detection unit (AC-DC step-down circuit 8, resistor) that detects that the lighting device 1 provided in the monitoring area is turned on and outputs an illumination on signal 9, a photocoupler 10 and a resistor 11), and a control unit (microcomputer 12) that outputs a test result of the internal circuit by the test unit when an illumination on signal is input.
[Selection] Figure 2

Description

  The present invention relates to an alarm device.

  The alarm device is provided with a test switch on the housing surface or the like for confirming whether the alarm device functions normally. By operating this test switch, the internal circuit is tested for abnormalities, and the test result is output as an alarm. Thereby, the user can confirm whether the alarm device functions normally (for example, refer to Patent Document 1).

JP 2007-11829 A (paragraph 0015, FIG. 1)

  In order to keep the function of the alarm device in a normal state, it is preferable to confirm by conducting a test periodically. For this reason, a periodic test (for example, every month) is recommended to the user in the instruction manual or the like. However, since the alarm device is installed at a high position such as a ceiling surface, it takes a lot of trouble to operate the test switch. In other words, there is a problem that it takes a lot of time to check whether the alarm device functions normally. In addition, there is a problem that the test itself is forgotten.

  The present invention has been made to solve the above-described problems, and an object thereof is to obtain an alarm device capable of confirming whether the alarm device functions normally without causing a user to take trouble. And

  An alarm device according to the present invention is an alarm device including an abnormality detection unit that detects an abnormality in a monitoring region, and an alarm unit that outputs an abnormality alarm when the abnormality detection unit detects an abnormality in the monitoring region. When a test unit that performs a circuit test, a control that turns on a lighting device provided in the monitoring area is detected, an illumination on detection unit that outputs an illumination on signal, and an illumination on signal are input And a control unit that outputs a test result of the internal circuit by the test unit.

  Further, power is supplied from a power source other than the power source that supplies power to the lighting device.

  The illumination-on detection unit includes at least one of a power supply detection unit that detects that power is supplied to the illumination device and a light detection unit that detects that the illumination device is turned on by a light detection element.

  The alarm unit includes a light-emitting diode for abnormality display, and uses the light-emitting diode as a light detection element.

  The control unit outputs a test result of the internal circuit when the illumination on signal is input a predetermined number of times.

  In the present invention, the internal circuit is tested at a predetermined timing. Then, when an operation for turning on the lighting device is performed by a user or the like, a test result of the internal circuit is output. This eliminates the need for the user to operate the test switch. Therefore, it is possible to periodically notify the user of the test result of the internal circuit of the alarm device (whether or not the alarm device functions normally) without requiring the user to take time.

  Moreover, the power supply for supplying power to the alarm device is different from the power supply for supplying power to the lighting device. For this reason, even when the power supply for supplying power to the lighting equipment cannot supply power (for example, a power failure), an abnormality alarm can be output if an abnormality in the monitoring area is detected, and the internal circuit test It can be performed.

  The illumination-on detection unit includes at least one of a power supply detection unit that detects that power is supplied to the illumination device and a light detection unit that detects that the illumination device is turned on by a light detection element. When the illumination-on detection unit includes the power supply detection unit, it is possible to reliably detect that an operation for turning on the illumination device has been performed even when the light bulb of the illumination device is turned off. When the illumination on detection unit includes the light detection unit, it is not necessary to connect the electric wiring for supplying power to the illumination device and the alarm device. For this reason, the alarm device can be easily retrofitted to an existing property.

  Moreover, when the illumination on detection part is provided with the light detection part, the number of parts of an alarm device can be reduced by using the light emitting diode for abnormal display of the monitoring area as a light detection element.

  In addition, the power consumption can be reduced by outputting the test result of the internal circuit by the test unit when the illumination ON signal is input a predetermined number of times. In addition, it is possible to notify the user of the test result of the internal circuit of the alarm device (whether or not the alarm device functions normally) at an appropriate frequency with a certain interval.

It is a perspective view which shows the monitoring space where the fire alarm device which concerns on this Embodiment 1 was installed. It is a circuit block diagram which shows the internal circuit of the fire alarm which concerns on this Embodiment 1. It is a flowchart which shows the main operation | movement of the fire alarm which concerns on this Embodiment 1. FIG. It is a flowchart which shows the fire monitoring operation | movement of the fire alarm device which concerns on this Embodiment 1. FIG. It is a flowchart which shows the disconnection monitoring test operation | movement of the fire alarm device which concerns on this Embodiment 1. FIG. It is a flowchart which shows the voltage monitoring test operation | movement of the fire alarm device which concerns on this Embodiment 1. FIG. It is a flowchart which shows the test determination operation | movement of the fire alarm which concerns on this Embodiment 1. FIG. It is a flowchart which shows the test alarm output operation | movement of the fire alarm device which concerns on this Embodiment 1. FIG. It is a circuit block diagram which shows the internal circuit of the fire alarm which concerns on this Embodiment 2. It is a circuit block diagram which shows the internal circuit of the fire alarm which concerns on this Embodiment 3. It is a flowchart which shows the main operation | movement of the fire alarm which concerns on this Embodiment 4. It is a flowchart which shows the test determination operation | movement of the fire alarm device which concerns on this Embodiment 4. FIG.

Embodiment 1 FIG.
There are various alarm devices such as a fire alarm device and a gas leak alarm device. In addition, fire alarms include a fire alarm that detects smoke with a light emitting element and a light receiving element, a fire alarm that detects heat with a thermal element, and a fire alarm that detects flame with a pyroelectric element. An alarm is present. In this Embodiment 1, the case where this invention is implemented to the fire alarm which detects heat with the thermistor which is a thermal element is demonstrated.

  FIG. 1 is a perspective view showing a monitoring space in which a fire alarm device according to the first embodiment is installed. FIG. 2 is a circuit configuration diagram showing an internal circuit of the fire alarm. The fire alarm device 4 according to the first embodiment will be described with reference to FIGS. 1 and 2.

  In a dwelling that is a monitoring space, a lighting device 1 is installed on the ceiling surface, and a lighting switch 2 is installed on the wall surface. The lighting device 1 is connected to an electrical wiring 3 with a lighting switch 2 interposed. When the lighting switch 2 is turned on, the lighting device 1 is lit by being supplied with electric power via the electric wiring 3. A fire alarm 4 is also installed on the ceiling.

  The fire alarm 4 includes a fire detection unit, a microcomputer as a control unit (hereinafter referred to as a microcomputer 12), an illumination on detection unit, a test unit for testing an internal circuit, a power source 6, and the like. As will be described later, the microcomputer 12 also functions as a test unit.

(Power supply)
For example, the power source 6, which is a lithium battery, constantly supplies power to the microcomputer 12 and the like via the constant voltage circuit 7. Through the constant voltage circuit 7, stable power supply to the microcomputer 12 is possible. Further, by constantly supplying power from a power source 6 (not shown) that supplies power to the lighting device 1, regardless of whether or not power is supplied to the lighting device 1, it is possible to detect an abnormality in the monitoring area. A fire can always be detected. Note that the microcomputer 12 may be connected to the electrical wiring 3 upstream of the lighting switch 2 to supply power to the microcomputer 12. Even if it does in this way, a fire can always be detected irrespective of whether electric power is supplied to the lighting equipment 1 or not. In the first embodiment, power is supplied to the lighting device 1 so that a fire can be detected even when a power source (not shown) that supplies power to the lighting device 1 cannot supply power (for example, a power failure). The power is always supplied to the microcomputer 12 by a power source 6 different from the power source to be used. Note that the power source 6 does not necessarily need to be constantly supplied with power. For example, power may be supplied in pulses at intervals that do not affect fire detection.

(Fire detection part)
The fire detection unit includes a thermistor 20 and a resistor 21. The thermistor 20 and the resistor 21 are connected in series, and a constant voltage is applied from both ends of the thermistor 20 and the resistor 21 via the constant voltage circuit 7. Moreover, the front-end | tip part of the thermistor 20 is provided in the surface vicinity of the housing | casing of the fire alarm 4 (shown in FIG. 1). Thereby, heat at the time of fire is easily transmitted to the thermistor 20. The microcomputer 12 receives a voltage divided by a resistance ratio by a thermistor 20 and a resistor 21. Since the resistance value of the thermistor 20 changes depending on the temperature, when the thermistor 20 is warmed during a fire, the voltage value between the thermistor 20 and the resistor 21 changes. The microcomputer 12 determines that a fire has occurred when the voltage value between the thermistor 20 and the resistor 21 exceeds, for example, a fire level. That is, the fire flag 25a of the storage unit 25 provided in the microcomputer 12 is set.

(Lighting detection unit)
The illumination-on detection unit according to the first embodiment includes a power supply detection unit that detects that power is supplied to the illumination device 1. The illumination on detection unit (power supply detection unit) includes an AC-DC step-down circuit 8, a resistor 9, a photocoupler 10, a resistor 11, and the like. The AC-DC step-down circuit 8 is connected to the branch electrical wiring 5 branched from the electrical wiring 3. When the illumination switch 2 is turned on, an AC voltage is applied to the AC-DC step-down circuit 8 from the power source via the branch electrical wiring 5. The AC-DC step-down circuit 8 converts this AC voltage into a DC voltage, and applies the DC voltage to the resistor 9 and the photocoupler 10 (hereinafter, this DC voltage is referred to as a step-down constant voltage). As a result, the photocoupler 10 is turned on and outputs an illumination on signal. When the photocoupler 10 outputs the illumination on signal, the terminal of the microcomputer 12 that has been pulled up by the resistor 11 and to which the constant voltage has been input is grounded, so that the illumination on signal is input to the microcomputer 12.

  In the first embodiment, the AC-DC step-down circuit 8 generates a step-down constant voltage, and supplies the step-down constant voltage to the photocoupler 10. However, if a photocoupler operating with an AC voltage is used, the branch electrical wiring 5 can be directly connected to the photocoupler without using the AC-DC step-down circuit 8. Moreover, it is good also as a structure which outputs a transfer signal from the illuminating device 1 or the illumination switch 2. FIG. Then, this transfer signal may be input to the microcomputer 12.

(Test Department)
In the first embodiment, a voltage drop monitoring test and a disconnection monitoring test are performed as internal circuit tests.
In the voltage drop monitoring test, the voltage monitoring circuit 19 tests whether the voltage value of the power source 6 is not more than a predetermined value. When the voltage value of the power supply 6 becomes a predetermined value or less, the microcomputer 12 is notified of the voltage drop of the power supply 6. That is, when the voltage value of the power source 6 becomes equal to or lower than a predetermined value, the voltage drop flag 25d of the storage unit 25 provided in the microcomputer 12 is set.
The disconnection monitoring test is performed by the microcomputer 12 monitoring the voltage value between the thermistor 20 and the resistor 21. When the thermistor 20 is disconnected, the voltage value between the thermistor 20 and the resistor 21 becomes the ground voltage. When the voltage value between the thermistor 20 and the resistor 21 becomes the ground voltage, the microcomputer 12 determines that the thermistor 20 (fire detection unit) is disconnected. That is, the disconnection flag 25b of the storage unit 25 provided in the microcomputer 12 is set.

  Although the disconnection of the thermistor 20 is detected in the first embodiment, the deterioration of the thermistor 20 may be determined. For example, when the voltage value between the thermistor 20 and the resistor 21 falls within a predetermined range, it can be determined that the thermistor 20 has deteriorated.

(Control unit and alarm unit)
The fire alarm device 4 according to the first embodiment is provided with an alarm unit for sound output and an alarm unit for display output (lighting or blinking).
The alarm unit for outputting sound includes a voice synthesis circuit 13, a speaker 14, and the like.
The alarm unit for displaying and outputting includes a transistor 15, a resistor 16, a light emitting diode 17, and the like. When the transistor 15 is energized from the microcomputer 12 and the transistor 15 is switched, a voltage is applied from the constant voltage circuit 7 via the resistor 16 and the light emitting diode 17 is turned on.
The control unit notifies the user of the fire alarm and the test result via the alarm unit for outputting sound and the alarm unit for outputting display. Note that outputting a test result every time power is supplied to the lighting device 1 is uneconomical because of increased power consumption. In addition, the alarm frequency is frequent and may cause discomfort to the user. For this reason, the fire alarm device 4 (microcomputer 12) according to the first embodiment, when the lighting on signal is input a predetermined number of times (when the user performs the operation of turning on the lighting device 1 a predetermined number of times or more), The test result is output.

  The fire alarm device 4 also includes a switch 18 for instructing the microcomputer 12 to test the internal circuit (for instructing the output of the test result), similarly to the conventional fire alarm device. The user can test the internal circuit by operating the switch 18.

(Operation)
Next, the operation of the fire alarm 4 will be described.
FIG. 3 is a flowchart showing the main operation of the fire alarm according to the first embodiment. 4 to 8 are flowcharts showing the operations shown in FIG.

  First, the main operation of the fire alarm 4 will be described with reference to FIG. When power is supplied by connecting the power source 6, the microcomputer 12 clears all the flags in the storage unit 25 and proceeds to step S2 (step S1). In step S2, the microcomputer 12 clears all counters (illumination on signal counter 25f) in the storage unit 25. In step S3, a fire is monitored (details will be described later with reference to FIG. 4). In step S4, a disconnection monitoring test of the thermistor 20 is performed (details will be described later with reference to FIG. 5). In step S5, a voltage drop monitoring test of the power source 6 is performed (details will be described later with reference to FIG. 6). In step S6, it is determined whether to output a test result (test normal) based on steps S4 and S5 (details will be described later with reference to FIG. 7). In step S7, it is determined what kind of output is to be performed. That is, it is determined whether to output a fire alarm or a test result (details will be described later with reference to FIG. 8). After step S7 ends, the process returns to step S3, and fire monitoring and internal circuit testing are performed again. That is, the fire alarm device 4 performs an internal circuit test or the like every predetermined time.

  Details of the fire monitoring operation shown in step S3 of FIG. 3 will be described with reference to FIG. The microcomputer 12 determines whether or not a fire has occurred based on the voltage value between the thermistor 20 and the resistor 21 (step S301). If it is determined that a fire has occurred, the fire flag 25a of the storage unit 25 provided in the microcomputer 12 is set (step S302), and the process proceeds to the disconnection monitoring test operation in step S4. If it is determined that no fire has occurred, the fire flag 25a of the storage unit 25 provided in the microcomputer 12 is cleared (step S303), and the process proceeds to a disconnection monitoring test operation in step S4.

  Details of the disconnection monitoring test operation shown in step S4 of FIG. 3 will be described with reference to FIG. The microcomputer 12 determines whether or not the fire flag 25a of the storage unit 25 is set (step S401). When the fire flag 25a is set, the disconnection monitoring test is terminated, and the process proceeds to the voltage monitoring test operation in step S5. This is because when a fire has occurred, it is necessary to immediately output a fire alarm. When the fire flag 25a is not set, the microcomputer 12 determines whether or not the thermistor 20 is disconnected based on the voltage value between the thermistor 20 and the resistor 21 (step S402). When it is determined that the thermistor 20 is disconnected, the disconnection flag 25b of the storage unit 25 is set (step S403), and the process proceeds to the voltage monitoring test operation of step S5. When it is determined that the thermistor 20 is not disconnected, the disconnection flag 25b of the storage unit 25 is not set, and the process proceeds to the voltage monitoring test operation in step S5.

  Details of the voltage monitoring test operation shown in step S5 of FIG. 3 will be described with reference to FIG. The microcomputer 12 determines whether or not the fire flag 25a of the storage unit 25 is set (step S501). If the fire flag 25a is set, the voltage monitoring test is terminated, and the process proceeds to the test determination operation in step S6. This is because when a fire has occurred, it is necessary to immediately output a fire alarm. If the fire flag 25a is not set, it is determined whether or not the voltage of the power source 6 has decreased (step S502). If it is determined that the voltage of the power source 6 has decreased, the voltage decrease flag 25d of the storage unit 25 is set (step S503), and the process proceeds to the test determination operation of step S6. If it is determined that the voltage of the power source 6 has not decreased, the voltage decrease flag 25d of the storage unit 25 is not set, and the process proceeds to the test determination operation in step S6.

  Details of the test determination operation shown in step S6 of FIG. 3 will be described with reference to FIG. The microcomputer 12 determines whether or not the power supply of the lighting device 1 is stopped (whether or not the lighting device 1 is turned off) based on whether or not the lighting on signal is input (step S601). When the power supply of the lighting device 1 is stopped, that is, when the lighting on signal is not input, the lighting off flag 25e of the storage unit 25 is set (step S602), and the process proceeds to step S603. When the power supply of the lighting device 1 is not stopped, that is, when the lighting on signal is input, the lighting off flag 25e of the storage unit 25 is not set, and the process proceeds to step S603.

In step S <b> 603, the microcomputer 12 determines whether power is supplied to the lighting device 1 (whether the lighting device 1 is lit) based on whether the lighting on signal is input. When power is supplied to the lighting device 1, that is, when the lighting on signal is input, the process proceeds to step S604. When power is not supplied to the lighting device 1, that is, when the lighting on signal is not input, the process proceeds to step S607.
In step S604, the microcomputer 12 determines whether the illumination off flag 25e of the storage unit 25 is set. When the illumination off flag 25e is set, it is determined that the illumination has been turned on from off, the illumination on signal counter 25f of the storage unit 25 is counted up (step S605), and the illumination off flag 25e of the storage unit 25 is cleared (step S605). S606). Then, the process proceeds to step S607. If the illumination off flag 25e is not set, the process proceeds to step S607.

  That is, in the processes from step S601 to step S604, it is determined whether or not the lighting device 1 is turned on during the previous test determination operation (step S6) from the previous test determination operation (step S6). Therefore, if the lighting device 1 continues to be turned off between the previous test determination operation (step S6) and the current test determination operation (step S6), the illumination on signal counter 25f of the storage unit 25 is not counted up (step S603). If the lighting device 1 continues to be lit between the previous test determination operation (step S6) and the current test determination operation (step S6), the illumination on signal counter 25f of the storage unit 25 is not counted up (step S604). . Thereby, in step S605, the microcomputer 12 can grasp | ascertain the frequency | count that the user turned on the illuminating device 1. FIG.

  In step S607, the microcomputer 12 determines whether or not the fire flag 25a in the storage unit 25 is set (step S607). When the fire flag 25a is set, the test determination operation is terminated, and the process proceeds to the test alarm output operation in step S7. This is because when a fire has occurred, it is necessary to immediately output a fire alarm. If the fire flag 25a is not set, the microcomputer 12 determines whether or not the switch 18 has been operated (step S608). If the switch 18 is operated, the user must be informed of the test result of the internal circuit, and the process advances to step S610.

  When the switch 18 is not operated, the microcomputer 12 determines whether or not the number stored in the illumination on signal counter 25f of the storage unit 25 is equal to or greater than a predetermined value (step S609). That is, it is determined whether or not the user has performed the operation of turning on the lighting device 1 a predetermined number of times or more. If the number stored in the illumination on signal counter 25f is greater than or equal to a predetermined value, the process proceeds to step S610. If the number stored in the illumination on signal counter 25f is smaller than the predetermined value, the process proceeds to a test alarm output operation in step S7. Steps S610 to S612 are steps for determining whether or not the internal circuit is normal. For example, if the predetermined number is 1, every time the user performs the lighting operation of the lighting device 1, it is determined whether or not the internal circuit is normal.

  In step S610, the microcomputer 12 determines whether or not the disconnection flag 25b of the storage unit 25 is set. If the disconnection flag 25b is not set, the process proceeds to step S611. If the disconnection flag 25b is set, the process proceeds to a test alarm output operation of step S7. In step S611, the microcomputer 12 determines whether or not the voltage drop flag 25d of the storage unit 25 is set. If the voltage drop flag 25d is not set, the process proceeds to step S612. If the voltage drop flag 25d is set, the process proceeds to a test alarm output operation in step S7. In step S612, the microcomputer 12 determines that the disconnection of the thermistor 20 and the voltage drop of the power source 6 have not occurred, and sets the test normal flag 25c of the storage unit 25. And it progresses to the test warning output operation | movement of step S7.

  Details of the test alarm output operation shown in step S7 of FIG. 3 will be described with reference to FIG. The microcomputer 12 determines whether or not the fire flag 25a of the storage unit 25 is set (step S701). If the fire flag 25a is set, the process proceeds to step S702 and a fire alarm is output. For example, a fire alarm sound is acoustically output as a fire alarm, and the light emitting diode 17 is turned on and displayed. And it returns to the fire monitoring operation | movement of step S3. If the fire flag 25a is not set, the process proceeds to step S703. In step S703, the microcomputer 12 determines whether or not the disconnection flag 25b of the storage unit 25 is set. When the disconnection flag 25b is set, the disconnection flag 25b is cleared (step S704), and a test abnormality alarm is output (step S707). For example, a test abnormality sound is acoustically output as a test abnormality alarm, and the light emitting diode 17 is blinked and displayed. And it returns to the fire monitoring operation | movement of step S3. If the disconnection flag 25b is not set, the process proceeds to step S705.

  In step S705, the microcomputer 12 determines whether or not the voltage drop flag 25d of the storage unit 25 is set. If the voltage drop flag 25d is set, the voltage drop flag 25d is cleared (step S706), and a test abnormality alarm is output (step S707). For example, a test abnormality sound is acoustically output as a test abnormality alarm, and the light emitting diode 17 is blinked and displayed. And it returns to the fire monitoring operation | movement of step S3. If the voltage drop flag 25d is not set, the process proceeds to step S708. In step S708, the microcomputer 12 determines whether or not the test normal flag 25c in the storage unit 25 is set. If the test normal flag 25c is set, the test normal flag 25c is cleared (step S709), and a test normal alarm is output (step S710). For example, a test normal sound is acoustically output as a test normal alarm, and the light emitting diode 17 is turned on for display output. Then, the illumination on signal counter 25f is cleared (step S711), and the process returns to the fire monitoring operation in step S3. If the test normal flag 25c is not set, no alarm is output and the process returns to the fire monitoring operation in step S3.

  In the first embodiment, when the user performs an operation of turning on the lighting device 1 a predetermined number of times or more, display output and sound output are performed as alarm outputs. However, the predetermined number of times may be different for display output and sound output. For example, display output may be performed every time the user performs an operation of turning on the lighting device 1, and sound output may be performed when the user performs an operation of lighting the lighting device 1 twice or more. The predetermined number of times of outputting the display output and the sound output may be set by the user by a setting unit such as a dip switch. Moreover, you may notify a test result by either display output or sound output. In addition to the alarm unit for the fire alarm, an alarm unit for alarming the test result may be provided.

  In the fire alarm device 4 configured in this way, when the user performs the lighting operation of the lighting device 1 a predetermined number of times or more, there is no abnormality in the internal circuit (the fire alarm device 4 functions normally). Can inform the user. Therefore, the user is not required to take time.

  Further, a power source 6 that is different from a power source that supplies power to the lighting device 1 is always supplied to the microcomputer 12. Therefore, even when a power source (not shown) that supplies power to the lighting device 1 cannot supply power (for example, a power failure), fire detection can be performed.

  Moreover, since the illumination on detection part is provided with the electric power supply detection part, even when the light bulb of the illuminating device 1 is cut off, it is possible to reliably detect that an operation for turning on the illuminating device 1 has been performed.

Embodiment 2. FIG.
In the first embodiment, lighting of the lighting device 1 is detected by the lighting on detection unit including the power supply detection unit. Even if lighting of the lighting device 1 is detected by the light detection element, the present invention can be implemented. In the second embodiment, items that are not particularly described are the same as those in the first embodiment, and the same functions and configurations are described using the same reference numerals.

  FIG. 9 is a circuit configuration diagram showing an internal circuit of the fire alarm according to the second embodiment. The illumination on detection unit of the fire alarm device 4 according to the second embodiment includes a light detection unit that detects lighting of the lighting device 1 by the light detection element 22. The illumination on detection unit (light detection unit) includes a light detection element 22, a wiring 23, and the like. The light detection element 22 is, for example, a photodiode. By receiving light from the lighting device 1, a voltage is generated at both ends of the light detection element 22. This voltage is input to the microcomputer 12 as an illumination on signal. In the second embodiment, a light detection element that generates a voltage by receiving light is used. However, a light detection element (for example, a photoresistor) whose resistance value changes by receiving light may be used.

  In addition, although the illumination ON detection part of this Embodiment 2 is provided only with the light detection part, of course, you may provide the electric power supply detection part shown in Embodiment 1.

  In the fire alarm device 4 configured as described above, it is not necessary to separately provide the branch electric wiring 5 for connecting the electric wiring 3 for supplying power to the lighting device 1 and the fire alarm device 4. For this reason, the fire alarm 4 can be easily retrofitted to an existing property.

Embodiment 3 FIG.
It is also possible to use the light emitting diode 17 constituting the alarm unit as a substitute for the light detection element 22 shown in the second embodiment. In Embodiment 3, items that are not particularly described are the same as those in Embodiment 1 or Embodiment 2, and the same functions and configurations are described using the same reference numerals.

  FIG. 10 is a circuit configuration diagram showing an internal circuit of the fire alarm device according to the third embodiment. The lighting-on detection unit of the fire alarm device 4 according to the third embodiment includes the light emitting diode 17 and the wiring 24. The wiring 24 has one end connected to the anode side of the light emitting diode 17 and the other end connected to the microcomputer 12.

  When the light emitting diode 17 does not display an alarm and does not receive the light from the lighting device 1, no voltage is generated across the light emitting diode 17. At this time, the light-emitting diode 17 that has received the light from the lighting device 1 generates a voltage at both ends thereof. This voltage is input to the microcomputer 12 as an illumination on signal. That is, the light emitting diode 17 is also used as a light detection element that detects lighting of the lighting device 1.

  In the fire alarm device 4 configured as described above, a dedicated light detection element is not provided for detecting the lighting of the lighting device 1, and the number of parts of the fire alarm device 4 can be reduced.

Embodiment 4 FIG.
In the first to third embodiments, whether or not there is an abnormality in the internal circuit (whether or not the fire alarm 4 functions normally) is periodically tested. When this is done, it may be tested whether there is no abnormality in the internal circuit (whether the fire alarm 4 functions normally). In the fourth embodiment, items not particularly described are the same as those in the first to third embodiments, and the same functions and configurations are described using the same reference numerals.

  FIG. 11 is a flowchart showing the main operation of the fire alarm device according to the fourth embodiment. FIG. 12 is a flowchart showing the test determination operation of FIG. In the first to third embodiments, the disconnection monitoring test operation (step S4) of the thermistor 20 and the voltage drop monitoring test operation (step S5) of the power source 6 that were in the main operation are the test determination operation (step S6). Has been implemented in. In the test determination operation (step S6), the disconnection monitoring test operation (step S4) and the voltage drop monitoring test operation (step S5) are performed when the switch 18 is operated and the user turns on the lighting device 1. This is performed when the operation is performed a predetermined number of times or more.

  Also in the fire alarm device 4 configured in this way, when the user performs the lighting operation of the lighting device 1 more than a predetermined number of times, there is no abnormality in the internal circuit (the fire alarm device 4 functions normally). Can inform the user. Therefore, the user is not required to take time.

  As described above, in the first to fourth embodiments, the disconnection monitoring test of the thermistor 20 and the voltage drop monitoring test of the power source 6 are performed as the internal circuit tests. However, these tests are only examples. For example, as an internal circuit test, whether or not sound is output from the speaker 14 may be tested.

Moreover, although the fire alarm device 4 which detects heat was demonstrated in Embodiment 1-Embodiment 4, this is an example to the last. For example, you may implement this invention to the fire alarm which detects smoke with a light emitting element and a light receiving element. As a test of the internal circuit, for example, the light receiving element output level is monitored. For example, you may implement this invention to the fire alarm which detects a flame with a pyroelectric element. As a test of the internal circuit, for example, the output level of the pyroelectric element when the test light is irradiated is monitored.
Needless to say, the present invention can be applied to an alarm device other than a fire alarm device such as a gas leak alarm device.

  DESCRIPTION OF SYMBOLS 1 Lighting equipment, 2 Lighting switch, 3 Electrical wiring, 4 Fire alarm, 5 branch electrical wiring, 6 Power supply, 7 Constant voltage circuit, 8 AC-DC step-down circuit, 9 Resistance, 10 Photocoupler, 11 Resistance, 12 Microcomputer, 13 Voice synthesis circuit, 14 Speaker, 15 Transistor, 16 Resistance, 17 Light emitting diode, 18 Switch, 19 Voltage monitoring circuit, 20 Thermistor, 21 Resistance, 22 Photodetection element, 23 Wiring, 24 Wiring, 25 Memory, 25a Fire flag 25b Disconnection flag, 25c Test normal flag, 25d Voltage drop flag, 25e Illumination off flag, 25f Illumination on signal counter.

Claims (5)

An anomaly detector that detects an anomaly in the monitoring area;
An alarm unit that outputs an abnormality alarm when the abnormality detection unit detects an abnormality in the monitoring area; and
An alarm device comprising:
A test unit for testing internal circuits;
An illumination on detection unit that detects that the lighting device provided in the monitoring area is controlled to be turned on and outputs an illumination on signal;
When the illumination on signal is input, a control unit that outputs a test result of the internal circuit by the test unit;
An alarm device comprising:   The alarm device according to claim 1, wherein power is supplied from a power source other than a power source that supplies power to the lighting device. The illumination on detection unit
The power supply detection part which detects that the electric power was supplied to the said illuminating device, and at least one of the photon detection part which detects that the said illuminating device was lighted with a photon detection element, The claim 1 or Claim characterized by the above-mentioned. Item 3. The alarm device according to item 2. The alarm unit includes a light emitting diode for abnormality display,
When the illumination on detection unit includes the light detection unit,
The alarm device according to claim 3, wherein the light-emitting diode is used as the light detection element. The controller is
The alarm device according to any one of claims 1 to 4, wherein when the illumination on signal is input a predetermined number of times, a test result of an internal circuit by the test unit is output.

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