JP4721664B2 - Alarm - Google Patents

Description

  The present invention relates to an alarm device that detects an abnormality in a monitoring area and issues an alarm.

  2. Description of the Related Art Conventionally, an alarm device that is installed in a monitoring area and detects various abnormalities occurring in the monitoring area and issues an alarm has been widely used. For example, in general buildings, underground malls, offices, or general houses, gas alarms that detect gas and emit gas leak alarms, and fire alarms that detect smoke and heat and generate fire alarms are used. As an example of such an alarm device, Patent Document 1 (Japanese Patent Laid-Open No. 10-124769) discloses an alarm device used by being attached to a ceiling surface or a wall surface of a general house or the like.

  In such an alarm device, in order to confirm the normality of the alarm function, an alarm device having an automatic inspection function has been proposed so that an operator can easily inspect the alarm device at the installation location. According to this automatic inspection function, for example, when an operator operates an inspection switch of an alarm device, an alarm is output for a predetermined time. More specifically, when the inspection switch is operated, an indicator light is turned on to warn of the occurrence of a fire or gas for a predetermined time, and a buzzer sound or voice message is sent from the speaker to notify the occurrence of a fire or gas. To do. In particular, among alarm devices, when the gas is detected, the main microcomputer is automatically shut off by performing a voltage output to the gas microcomputer meter outside the house. It was only done for hours, and the gas microcomputer meter cut off the main gas plug.

JP-A-10-124769

  However, at the time of inspection, there are a thing which wants to output a warning and a thing which does not want to output a warning depending on the situation. For example, for the voltage output at the time of inspection of the gas leak alarm, there is a case where it is desired to output in order to check the interlocking function with the gas microcomputer meter. Therefore, if such a voltage output is performed until such a worker is not at the installation location, there is a problem that the recovery work cannot be performed immediately. .

  This invention is made in view of the above, Comprising: It aims at providing the alarm device which can perform smoothly from an inspection to a return | restoration by performing only the alarm output corresponding to the inspection condition. .

In order to solve the above-described problems and achieve the object, the alarm device according to claim 1 is an alarm device that detects an abnormality in the monitoring region and issues an alarm, and provides an external device for the alarm device. An alarm output means for outputting an alarm, an inspection operation means for receiving an instruction for an inspection operation, and a predetermined first alarm for the external device when a predetermined first inspection instruction is issued through the inspection operation means. A predetermined second inspection instruction that can be output without causing the alarm output means to perform the output and without assuming that the first inspection instruction has been performed is performed via the inspection operation means. A warning control means for causing the alarm output means to perform a predetermined second alarm output for the external device different from the first alarm output, and the alarm output means is provided for the external device. Yes for voltage output A pressure output means, and the voltage output means performs a voltage output by the first voltage at a normal time when the occurrence of abnormality in the monitoring area is not detected, and when a predetermined abnormality occurrence is detected in the monitoring area In this case, a voltage output based on a second voltage different from the first voltage is performed, and the inspection control unit is configured to output the first alarm when the first inspection instruction is performed via the inspection operation unit. As the output, when the second voltage output is performed by the second voltage output means and the second inspection instruction is performed through the inspection operation means, the second alarm output is the second alarm output. The voltage output means performs voltage output by one voltage .

The alarm device according to claim 2 is a gas leak alarm device according to claim 1 , wherein the alarm device detects a gas leak in the monitoring region as the occurrence of an abnormality and gives an alarm. The voltage output means is the external device that does not cut off the gas supply when the voltage output by the first voltage is received, and the gas is output when the voltage output by the second voltage is received. to the external device to cut off the supply, intends row chromatic voltage output.

The alarm device according to claim 3 is the alarm device according to claim 1 or 2 , wherein the inspection control means operates the inspection operation means within a predetermined time after turning on the power to the alarm device. If the inspection operation means is operated after a lapse of a predetermined time after turning on the power to the alarm device, it is determined that the first inspection instruction has been performed. It is determined that the instruction has been given.
Further, the alarm device according to claim 4 is the alarm device according to any one of claims 1 to 3 , wherein the inspection control means is within a predetermined time after the occurrence of an abnormality in the monitoring area is detected. When the inspection operation means is operated, it is determined that the first inspection instruction has been performed.
Further, the alarm device according to claim 5 is the alarm device according to claim 1 , wherein the alarm device detects a gas leak and a fire occurrence in the monitoring region as the abnormality occurrence and issues a fire gas leak. An alarm device, comprising a fire interlocking signal transmission / reception control means for transmitting / receiving an interlocking signal to / from a fire alarm device that detects an occurrence of a fire in the monitoring region as the abnormality occurrence and issues an alarm, the inspection control means, When an instruction for interlocking inspection is given through the inspection operation means, the interlocking signal transmission / reception control means for the fire alarm signal is output to the fire alarm device.
The alarm device according to claim 6 is the fire alarm device according to claim 1 , wherein the alarm device detects a fire occurrence in the monitoring area as the abnormality occurrence and issues an alarm, A fire interlocking signal transmission / reception control means for transmitting / receiving an interlocking signal to / from a fire gas leak alarm device that detects and alarms gas leakage and fire occurrence in the monitoring area, the inspection control means, When an instruction for interlocking inspection is given through the inspection operation means, the interlocking signal output to the fire interlocking signal transmission / reception control means is output to the fire gas leak alarm device.

According to the alarm device according to claim 1, since the alarm output having different contents can be performed respectively when the first inspection operation and the second inspection operation are performed, Only the matched alarm output can be performed, and from the inspection to the return of the alarm device can be performed smoothly.

According to the alarm device of the second aspect , it is possible to output a voltage that matches the inspection status of the alarm device, and to control the shut-off operation of the gas main plug by an external device such as a gas microcomputer meter.

According to the alarm device of the third aspect , a predetermined alarm output can be performed only when a predetermined operation is performed within a predetermined time after the power is turned on, and the contents differ depending on the time after the power is turned on. Inspection can be performed.

  Embodiments of an alarm device according to the present invention will be described below in detail with reference to the accompanying drawings. [I] First, the basic concept of the present invention will be described, then [II] each embodiment of the present invention will be described, and [III] Finally, modifications to the embodiment of the present invention will be described.

[I] Basic concept of the present invention First, the basic concept of the present invention will be described. The present invention relates to an alarm device that detects an abnormality in a monitoring area and issues an alarm. Here, a specific monitoring area is arbitrary, and can be arranged in each room such as a kitchen and a bedroom of a general house and each room of an office. Moreover, the abnormality detection target is arbitrary, for example, it detects smoke and issues a fire alarm, detects gas and issues a gas leak alarm, or detects carbon monoxide (CO) and incomplete combustion An alarm can be issued.

  Here, as the installation and operation mode of such an alarm device, there are a case where it is used alone and a case where it is used in conjunction with another alarm device. That is, when an abnormality is detected by a specific alarm device, an alarm is given only by the alarm device, and when an abnormality is detected by a specific alarm device, an alarm is issued by the alarm device or another alarm device. There is. In addition, the inspection for the alarm device is performed only by the alarm device instructed to be inspected (hereinafter referred to as “single inspection”), and the inspection in which the inspection is instructed and other alarm devices (hereinafter, “ It is called “linked inspection”).

  Under such a premise, the present invention is characterized in that different alarm outputs are performed based on the contents of the inspection instruction performed through the inspection operation means. As a result, only the alarm output that matches the inspection status can be performed. Here, the specific configuration of the inspection operation means is arbitrary, but in the following, it is configured as an inspection switch provided in the alarm device. The content of the alarm output is also arbitrary. For example, an alarm lamp such as an LED (Light Emitting Diode) is turned on or blinked, a buzzer sound or a voice message is output, and a voltage output to the gas microcomputer meter. Can be mentioned.

[II] Embodiments of the Invention Next, embodiments of the alarm device according to the invention will be described. However, the present invention is not limited to these examples.

  First, Example 1 will be described. The alarm device according to the first embodiment generally includes (1) an alarm output unit that outputs an alarm, an inspection operation unit that receives an instruction for an inspection operation, and a predetermined first inspection instruction via the inspection operation unit. Is performed, the predetermined first alarm output is made to be performed by the alarm output means, and when the predetermined second inspection instruction is issued via the inspection operation means, the first alarm output is different. Inspection control means for causing the alarm output means to perform a predetermined second alarm output; (2) the alarm output means includes a voltage output means for outputting a voltage when gas leakage is detected; The alarm output includes an output of a gas leak detection signal for a predetermined external device from the voltage output means, and the second alarm output includes an output of a gas leak detection signal for the predetermined external device from the voltage output means. And (3) the first inspection instruction is Within a predetermined time after power-on for the alarm, it is executed by being performed a predetermined operation on the inspection operation means, and the like as main features.

[Configuration of alarm system]
First, an outline and characteristics of an alarm system to which the alarm device according to the present embodiment is applied will be described. FIG. 1 is a system configuration diagram illustrating the overall configuration of the alarm system according to the present embodiment. As illustrated in FIG. 1, the alarm system according to the present embodiment is configured by connecting a fire gas leak alarm 1 and a plurality of fire alarms 2 by lead wires 3. Of these, the fire gas leak alarm 1 detects a fire and gas leak and gives an alarm, and is installed in a monitoring area where there is a possibility of fire occurrence or gas leak, for example, a kitchen in a general house. The fire alarm 2 detects the occurrence of a fire and gives an alarm, and is arranged in a monitoring area where there is a possibility of a fire, for example, a living area or a bedroom in a general house.

  In such an alarm system, for example, when the fire gas leak alarm 1 installed in the kitchen detects a fire, the alarm is performed by itself, and an interlock signal is sent to the fire alarm 2 in the living room or bedroom. The fire alarm device 2 in the living room or bedroom also gives an alarm. That is, in this case, the fire gas leak alarm 1 in the kitchen becomes the link source, and the fire alarm 2 in the living room or bedroom becomes the link destination. Here, although the transmission form of the interlocking signal is arbitrary, in the present embodiment, the interlocking signal is transmitted by short-circuiting the lead wire 3 connecting the fire gas leak alarm 1 and the plurality of fire alarms 2.

[Overall configuration and processing of fire gas leak alarm]
Next, the configuration of the fire gas leak alarm 1 according to the present embodiment will be described. As illustrated in FIG. 1, the fire gas leak alarm 1 includes a gas detection circuit 10, a smoke detection circuit 11, an indicator lamp circuit 12, a voltage output circuit 13, a sound alarm output circuit 14, a speaker 15, a fire interlocking signal. A transmission / reception circuit 16, an inspection circuit 17, an inspection switch 18, and a control unit 19 are provided.

  Among these, the gas detection circuit 10 is a gas detection means for detecting gas leakage in the monitoring region, measures methane and CO by a known method, and detects a voltage corresponding to the measured detected concentration of methane or CO. The signal is output to the control unit 19. The smoke detection circuit 11 measures the smoke concentration by a known method, and outputs a voltage detection signal corresponding to the measured smoke concentration to the control unit 19. The indicator lamp circuit 12 is indicator lamp control means for controlling lighting or blinking of a not-shown indicator lamp (for example, LED), and corresponds to alarm output means in the claims. Further, the voltage output circuit 13 outputs a voltage to an outdoor gas microcomputer meter (corresponding to a predetermined external device in claims) via a voltage output terminal 13a. It corresponds to the alarm output means and the voltage output means in the range.

  Here, the voltage output terminal 13a outputs to a gas microcomputer meter (not shown) at a voltage corresponding to the presence / absence of gas detection and the type of gas detected. For example, when there is an abnormality in the fire gas leak alarm 1, 0 v, when the fire gas leak alarm 1 is operating normally and no gas is detected (hereinafter referred to as “normal time”). ) 6v, when methane gas is detected (hereinafter referred to as “when gas is detected”), 12v when CO is detected (hereinafter referred to as “when gas is detected” as in the case of methane gas) Output 18v. On the other hand, in the gas microcomputer meter that has received such a voltage output, if the voltage output is 12 V or higher, control is performed to automatically shut off the gas main plug uniformly.

  The audio alarm output circuit 14 is an audio alarm output control means for starting or stopping the sounding of an alarm sound by the speaker 15, and corresponds to the alarm output means in the claims. The fire interlocking signal transmission / reception circuit 16 is a fire interlocking signal transmission / reception control means for transmitting / receiving an interlocking signal to / from the fire alarm device 2 via the lead wire 3. The inspection circuit 17 is an inspection control unit that receives an instruction for an inspection operation with respect to the fire gas leak alarm device 1 via the inspection switch 18. Here, the specific configuration of the inspection switch 18 is arbitrary, but in the present embodiment, the inspection switch 18 is configured as a ring suspended from a housing (not shown) of the fire gas leak alarm 1 via a string. An operation instruction can be input to the inspection circuit 17 by the user holding the ring with a finger or the like and pulling it down. The inspection circuit 17 and the inspection switch 18 correspond to the inspection operation means in the claims.

  The control unit 19 is a control unit that controls each unit of the fire gas leak alarm 1. The control unit 19 includes a detection processing unit 19a, an alarm processing unit 19b, an inspection processing unit 19c, and a storage unit 19d in terms of functional concept. Among these, the detection process part 19a is a detection process means which judges the presence or absence of a fire or a gas leak, and performs the predetermined control according to the judgment result. The alarm processing unit 19b is an alarm processing unit that performs predetermined control for performing various alarms when it is determined that a fire or a gas leak has occurred. The inspection processing unit 19c performs a predetermined inspection process based on an inspection instruction received via the inspection circuit 17 and the inspection switch 18, and corresponds to the inspection control means in the claims. The storage unit 19d is a storage unit that stores various kinds of information, and particularly stores a predetermined threshold value used for determining whether there is a fire or a gas leak in a nonvolatile manner. Although the specific form of the control part 19 comprised in this way is arbitrary, For example, it can comprise as a program which operate | moves on MPU (Micro Processor Unit) which has CPU and memory, and this MPU. The fire gas leak alarm 1 configured as described above is connected to a commercial power source via an outlet, and operates using the commercial power source as a power source.

  In the fire gas leak alarm 1 configured as described above, the fire and gas leak alarm is performed as follows. That is, when gas or smoke from the monitoring area enters a housing (not shown), a detection signal corresponding to the smoke concentration is output from the smoke detection circuit 11 to the control unit 19, or a detection signal corresponding to the gas concentration. Is output from the gas detection circuit 10 to the control unit 19. Then, the detection processing unit 19a of the control unit 19 compares the detection signal from the smoke detection circuit 11 or the gas detection circuit 10 with a predetermined threshold value stored in the storage unit 19d, and the smoke indicated by the detection signal. If the concentration or gas concentration exceeds the threshold, it is determined that a fire or gas leak has occurred, and a signal indicating that is output to the alarm processing unit 19b.

Receiving this, the alarm processing unit 19b controls the indicator lamp circuit 12 to turn on an indicator lamp (not shown), and controls the voice alarm output circuit 14 to output an alarm sound from the speaker 15. In addition, the alarm processing unit 19b controls the voltage output circuit 13 when a gas leak occurs, and a predetermined voltage (12v in the case of methane, 18v in the case of CO) from the voltage output terminal 13a. The voltage output is output. This voltage output is output to the gas microcomputer meter outside via the voltage output terminal 13a, and the gas main plug is shut off by the gas microcomputer meter. In addition, when a fire is detected , the alarm processing unit 19b causes the other alarm device 2 to output an interlocking signal via the fire interlocking signal transmitting / receiving circuit 16.

[Overview of overall configuration and processing of fire alarms]
Next, the configuration of the fire alarm device 2 according to the present embodiment will be described. As illustrated in FIG. 1, the fire alarm 2 includes a smoke detection circuit 20, an indicator light circuit 21, a sound alarm output circuit 22, a speaker 23, a fire-linked signal transmission / reception circuit 24, an inspection circuit 25, an inspection switch 26, and The control unit 27 is provided. Among these, the functions of the smoke detection circuit 20, the indicator light circuit 21, the sound alarm output circuit 22, the speaker 23, the fire interlocking signal transmission / reception circuit 24, the inspection circuit 25, and the inspection switch 26 are the same as the fire gas leak alarm 1 described above. The smoke detection circuit 11, the indicator lamp circuit 12, the sound alarm output circuit 14, the speaker 15, the fire-linked signal transmission / reception circuit 16, the inspection circuit 17, and the inspection switch 18 have no function related to the gas leak alarm. Except for, each is substantially the same, and the description thereof is omitted.

  The control unit 27 includes a detection processing unit 27a, an alarm processing unit 27b, an inspection processing unit 27c, and a storage unit 27d. The function of each of these parts is related to the function of the gas leak alarm with respect to the functions of the detection processing unit 19a, the alarm processing unit 19b, the inspection processing unit 19c, and the storage unit 19d of the control unit 19 of the fire gas leak alarm 1 described above. Each of them is substantially the same except that there is no symbol, and the description thereof is omitted. Here, the fire alarm device 2 incorporates a battery 28 as a main power source, and each unit is operated using electric power supplied from the battery 28.

  In the fire alarm device 2 configured as described above, the fire alarm is performed as follows. That is, when smoke from the monitoring region enters a housing (not shown), a detection signal corresponding to the smoke concentration is output from the smoke detection circuit 20 to the control unit 27. Then, the detection processing unit 27a of the control unit 27 compares the detection signal from the smoke detection circuit 20 with a predetermined threshold value stored in the storage unit 27d, and the smoke density indicated by the detection signal exceeds the threshold value. If it is, it is determined that a fire has occurred, and a signal indicating that is output to the alarm processing unit 27b. Receiving this, the alarm processing unit 27b controls the indicator lamp circuit 21 to light a predetermined indicator lamp, and controls the voice alarm output circuit 22 to output an alarm sound from the speaker 23. Further, the alarm processing unit 27b causes the fire gas leak alarm device 1 and other alarm devices 2 to output the interlock signal via the fire interlock signal transmission / reception circuit 24.

[Inspection process]
Next, the inspection process in the fire gas leak alarm 1 configured as described above will be described. Here, a case where a single check is executed by the fire gas leak alarm 1 will be described as an example. FIG. 2 is a flowchart of the inspection process according to the present embodiment.

First, the inspection processing unit 19c of the fire gas leak alarm device 1 monitors the presence or absence of an inspection instruction by monitoring the presence or absence of operation of the inspection switch 18 (step S1). And when there exists an inspection instruction | indication (step S1, Yes), the inspection process part 19c judges whether this inspection instruction | indication is a 1st inspection instruction | indication or a 2nd inspection instruction | indication. Although this determination criterion is arbitrary, for example, the time from the power-on of the fire gas leak alarm 1 is measured by a timer (not shown), and the inspection switch 18 is within a predetermined time (for example, 25 minutes) from the power-on. Is operated as a first inspection instruction (step S2, Yes), and when the inspection switch 18 is operated after a predetermined time from power-on, it is determined as a second inspection instruction ( Step S2, No).

  If the inspection processing unit 19c determines that the instruction is the first inspection instruction, the inspection processing unit 19c proceeds to step S3, and controls the alarm processing unit 19b to output a predetermined first alarm (step S3). For example, an unillustrated indicator lamp is turned on via the indicator lamp circuit 12 and a buzzer sound is emitted via the voice alarm output circuit 14 and the speaker 15. Further, the inspection processing unit 19c controls the voltage output circuit 13 as a part of the first alarm output, and sets the voltage output to the voltage at the time of gas detection, that is, 12v (or 18v may be used). Then, the inspection processing unit 19c continues this alarm state for a predetermined time (for example, 3 minutes) (step S4, No), stops the alarm when the predetermined time elapses (step S5), and returns to the normal state. .

  The effect of such a first alarm output is as follows. That is, the inspection performed within a predetermined time after the power is turned on is highly likely to be performed immediately after the installation of the fire gas leak alarm 1. Here, the installer of the fire gas leak alarm 1 is usually a person who can restore the gas main plug even if the gas main meter is cut off by the gas microcomputer meter. Smooth recovery is possible. Therefore, in this case, by performing a voltage output at the voltage at the time of gas detection, the gas microcomputer meter can shut off the gas main plug, and the normality of the function of the gas microcomputer meter can also be checked. It can be so.

  The predetermined time after turning on the power determined in step S2 can be about 25 minutes as an example, but is not limited to this, and it is necessary until the installer can turn on the power after the power is turned on. You can set any time you think. The predetermined time determined in step S4 can be about 3 minutes as an example, but is not limited thereto. For example, the accumulation time of the gas microcomputer meter is set (the fixed time when the gas main valve is automatically shut off only when the voltage output of the voltage at the time of gas detection continues for a certain time or longer). If it is, it is preferable to set it longer than this accumulation time in order to confirm the operation of the gas microcomputer meter. For example, when the accumulation time of the gas microcomputer meter is 1 minute, it is preferable that the alarm output of the fire gas leak alarm 1 is continued for 1 minute or more.

  On the other hand, if it is determined in step S2 that the instruction is the second inspection instruction, the inspection processing unit 19c proceeds to step S6 and controls the alarm processing unit 19b to perform a predetermined second different from the first alarm output. An alarm is output (step S6). For example, an unillustrated indicator lamp is turned on via the indicator lamp circuit 12 and a buzzer sound is emitted via the voice alarm output circuit 14 and the speaker 15. On the other hand, the inspection processing unit 19c controls the voltage output circuit 13 as a part of the second alarm output, and maintains the voltage output at the normal voltage, that is, 6v. The inspection processing unit 19c continues this alarm state until a predetermined time (for example, 3 minutes) elapses (step S7, No), stops the alarm when the predetermined time elapses (step S5), and is in a normal state. Return to.

  The effect of such second alarm output is as follows. That is, the inspection performed after elapse of a predetermined time or more after the power is turned on is highly likely to be a periodic inspection performed over time after the installation of the fire gas leak alarm 1. Periodic inspectors who perform such inspections are often those who cannot recover the gas main plug even if the gas microcomputer meter is shut off. And this cannot be recovered smoothly. Therefore, in this case, the inspection is performed without causing the gas microcomputer meter to shut off the gas main plug by maintaining the voltage of the voltage output at the normal voltage. Therefore, even if the inspection operator is a person who cannot restore the gas main stopper, the inspection and the return to the normal monitoring state can be performed smoothly.

[Effects of Example 1]
As described above, according to the first embodiment, only when a predetermined inspection operation is performed within a predetermined time after the power is turned on, the voltage output at the time of gas detection is performed, and the predetermined inspection operation is performed at other times. When the operation is performed, a normal voltage output is performed, so whether or not the gas main plug can be cut off can be changed according to the timing of inspection. It can be recovered.

  Next, an alarm device according to the second embodiment will be described. In addition to the features of the first embodiment, the alarm device according to the second embodiment includes inspection operator identification means for identifying the inspection operator, and the inspection operator identified by the inspection operator identification means The main feature is that, when the operator is a predetermined inspection operator, the first alarm output is performed by the alarm output means even when a predetermined second inspection instruction is given through the inspection operation means. And The structure and method that are not particularly described are the same as those in the first embodiment described above, and the same components are described with the same reference numerals.

[Configuration of fire gas leak alarm and fire alarm]
First, the configuration of the fire gas leak alarm 30 of the alarm system according to the present embodiment will be described (note that the fire alarm 2 can be configured in the same manner as in the first embodiment, and the description thereof is omitted). FIG. 3 is a system configuration diagram illustrating the overall configuration of the alarm system according to the present embodiment. As illustrated in FIG. 3, the fire gas leakage alarm device 30 according to the present embodiment includes an inspector identification unit 31 and a control unit 32 as a configuration different from that of the first embodiment.

  Among these, the inspector identification part 31 is for identifying the inspector who instruct | indicates the inspection with respect to the fire gas leak alarm 30, and respond | corresponds to the inspection operator identification means in a claim. The specific method of identifying the inspector is arbitrary. For example, when the inspector identifying unit 31 is configured as a keyhole into which only a special key can be inserted, and the inspector inserts the key into the keyhole, the inspector May be identified as a predetermined inspector. Alternatively, the inspector identification unit 31 is configured as a numeric keypad, and the inspector inputs his / her ID and password, thereby checking the ID and password stored in a storage unit 32d (to be described later) of the control unit 32, The person may be identified. Alternatively, the inspector identification unit 31 is configured as a card reader, and when the inspector reads his / her ID card with this card reader, the inspector is identified by collating with the card information stored in the storage unit 32d. You may do it. In addition, information such as a fingerprint, a retina, or a voiceprint may be collated using a known biometric technique.

  The control unit 32 includes a detection processing unit 32a, an alarm processing unit 32b, an inspection processing unit 32c, and a storage unit 32d. Among them, the detection processing unit 32a, the alarm processing unit 32b, and the storage unit 32d can be configured in the same manner as the detection processing unit 19a, the alarm processing unit 19b, and the storage unit 19d of the control unit 19 of the first embodiment. The description is omitted. However, inspector information necessary for inspector identification via the inspector identification unit 31 is stored in the storage unit 32d. The inspection processing unit 32c executes a predetermined inspection process based on an inspection instruction received through the inspection circuit 17 and the inspection switch 18, and corresponds to the inspection control means in the claims. In particular, when the inspection operator identified by the inspector identification unit 31 is a predetermined inspection operator, the inspection processing unit 32c issues a second inspection instruction via the inspection circuit 17 and the inspection switch 18. Even if it is performed, the first alarm output is performed.

[Inspection process]
Next, the inspection process in the fire gas leak alarm 30 configured as described above will be described. Here, a case where a single check is executed by the fire gas leak alarm 30 will be described as an example. FIG. 4 is a flowchart of the inspection process according to the present embodiment.

In FIG. 4, steps S10 to S16 are the same as steps S1 to S7 in FIG. That is, the inspection processing unit 32c monitors whether or not the inspection switch 18 is operated (step S10), and determines whether the inspection instruction is the first inspection instruction or the second inspection instruction based on the elapsed time after the power is turned on. Judgment (step S11), if it is the first inspection instruction, an alarm output including 12v or 18v voltage output is performed (step S12), and after a predetermined time has elapsed (step S13, Yes), an alarm is issued. Stop (step S14). In addition, in the case of the second inspection instruction, the inspection processing unit 32c outputs an alarm including a 6v voltage output (Step S15), and stops the alarm after a predetermined time has elapsed (Step S16, Yes). (Step S14).

  Here, unlike the case of the first embodiment, when the inspection processing unit 32c determines that it is the second inspection instruction in Step S11 (No in Step S11), the inspection operator who instructed the inspection in Step S10. Is a predetermined inspection operator (here, a gas inspector) or not (step S17). For example, it is determined whether or not the ID and password input by the inspection operator match the ID and password of the gas inspector stored in the storage unit 32d in FIG. It is judged that.

Then, when the inspection operator is not a gas inspector, the inspection processing unit 32c determines that the gas main plug cannot be restored, proceeds to step S15, and outputs an alarm output including a 6v voltage output. the causes (step S15). On the other hand, when the inspection operator is a gas inspector, the inspection processing unit 32c determines that the gas main stopper can be restored, and proceeds to step S12 to perform 12v (or 18v). An alarm output including a voltage output is performed (step S12).

  The effect of such alarm output is as follows. In other words, in the first embodiment, assuming that the inspection performed after a predetermined time has elapsed since the power was turned on is an inspection by a person who cannot restore the gas main plug shut-off, The inspection was carried out without executing the shut-off. In contrast, in this embodiment, even if the inspection is performed after a predetermined time has elapsed since the power was turned on, in the case of the inspection performed by the gas inspector, it is better to have the gas microcomputer meter shut off. Judging that it is preferable, the gas microcomputer meter is made to shut off the gas main plug by performing a voltage output of 12v or 18v. In this case, a comprehensive inspection including the gas microcomputer meter can be performed even after a predetermined time has elapsed since the power was turned on.

[Effects of Example 2]
As described above, according to the second embodiment, even after a predetermined time or more has elapsed since the power was turned on, whether or not the inspection operator is a gas inspector is identified. By performing a voltage output at the time of gas detection, a more comprehensive inspection including a gas microcomputer meter can be performed.

[III] Modifications to the Embodiments Each embodiment of the present invention has been described above, but the specific configuration and method of the present invention are within the scope of the technical idea of each invention described in the claims. Modifications and improvements can be made arbitrarily. Hereinafter, such a modification will be described.

[Alarm]
The alarm device to which the present invention can be applied is not limited to those shown in the above embodiments, and can be similarly applied to an alarm device that detects only gas. Moreover, it is good also as a structure which can connect an alarm device also to an intercom or a housing information panel.

[About interlocking mode]
Moreover, in the said Example, although the case where the independent inspection was performed by the fire gas leak alarm 1, 30 was demonstrated as an example, the same operation can be performed also at the time of an interlocking inspection. For example, when the inspection switch 18 of the fire gas leak alarm 1 is pulled for less than 5 seconds, an individual inspection instruction is given, and when the inspection switch 18 is pulled for 5 seconds or more When it is determined that it is an instruction for interlocking inspection and when it is determined that it is an instruction for interlocking inspection, an interlocking signal is output via the fire interlocking signal transmitting / receiving circuit 16. On the contrary, when the inspection switch 26 of the alarm device 2 is operated by a predetermined method, an alarm signal is output to the fire gas leak alarm devices 1 and 30 by outputting an interlock signal to the fire gas leak alarm devices 1 and 30. Output can also be performed. In this case, different alarm outputs can be performed based on the operation method for the inspection switch 26 of the alarm device 2 and the elapsed time after power-on of the fire gas leak alarm devices 1 and 30 or the alarm device 2.

[Operating means]
As the operation means for instructing the inspection operation, any means other than the inspection switch 18 can be used. For example, a dedicated inspection switch for performing the first alarm output and a dedicated inspection switch for performing the second alarm output may be provided separately from each other. Further, as a form of operation means, in addition to providing directly to the fire gas leak alarms 1 and 30 and the fire alarm unit 2, infrared communication is performed between the fire gas leak alarms 1 and 30 and the fire alarm unit 2. You may comprise as a remote control to perform.

[About inspection instructions]
In addition, the first inspection instruction and the second inspection instruction can be arbitrarily changed. For example, when a gas leak is detected instead of the elapsed time after the power is turned on, the inspection is instructed within a predetermined time thereafter. In such a case, a 12v or 18v voltage output may be performed. In other words, when a gas leak is detected, the gas company is automatically contacted, so there is a high possibility that the gas company inspector is rushing to the place where the fire gas leak alarm is installed. In some cases, the inspection can be performed including the shut-off of the gas main valve.

[Alarm output]
Further, the contents of the first alarm output and the second alarm output can be arbitrarily modified. For example, it is possible to change not only the voltage value in the voltage output but also the lighting or blinking state of the indicator lamp or the contents of the alarm message. Furthermore, regarding the types of inspection instructions and alarm outputs, not only the first and second types but also three or more types of alarm outputs can be distinguished based on three or more types of inspection instructions.

[Problems to be solved and effects of the invention]
In addition, the problems to be solved by the present invention and the effects of the invention are not limited to the above contents, and the present invention solves problems not described above or effects not described above. In some cases, only a part of the described problems can be solved, or only a part of the described effects can be achieved. That is, as long as different alarm outputs can be performed according to the inspection operation, the problem of the present invention is solved.

[About control]
Further, all or any part of the control described as being automatically performed in each of the above embodiments may be performed manually, and conversely, all or any of the control described as being performed manually is performed. The part may be automated based on a known technique or the idea described above. In addition, each control unit and each processing block of each control unit shown in each embodiment can actually be configured as a CPU and a computer program read and executed by the CPU, or a hard-wired Can be configured with logic. Each electrical component described above is functionally conceptual, and does not necessarily need to be physically configured as illustrated, and the specific form of distribution / integration of each unit is arbitrary. In addition, the processing procedure and the control procedure shown in the document and the drawings can be arbitrarily changed unless otherwise specified.

  As described above, the alarm device according to the present invention is useful for inspecting the alarm device with contents that match the inspection status, and is suitable for smoothly performing the inspection from the inspection to the return of the alarm device.

1 is a system configuration diagram illustrating an overall configuration of an alarm system according to Embodiment 1. FIG. 3 is a flowchart of an inspection process according to the first embodiment. FIG. 3 is a system configuration diagram illustrating an overall configuration of an alarm system according to a second embodiment. 10 is a flowchart of an inspection process according to the second embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,30 Fire gas leak alarm device 2 Fire alarm device 3 Lead wire 10 Gas detection circuit 11, 20 Smoke detection circuit 12, 21 Indicator light circuit 13 Voltage output circuit 14, 22 Voice alarm output circuit 15, 23 Speaker 16, 24 Fire interlocking signal transmission / reception circuit 17, 25 Inspection circuit 18, 26 Inspection switch 19, 27, 32 Control unit 19a, 27a, 32a Detection processing unit 19b, 27b, 32b Alarm processing unit 19c, 27c, 32c Inspection processing unit 19d, 27d, 32c storage unit

Claims (6)

An alarm device that detects an abnormality in a monitoring area and gives an alarm,
An alarm output means for outputting an alarm to an external device for the alarm device;
Inspection operation means for receiving instructions for inspection operation;
When a predetermined first inspection instruction is given through the inspection operation means, the alarm output means is made to output a predetermined first alarm for the external device, and the first inspection instruction is issued. When a predetermined second inspection instruction that can be performed without presupposing that it has been issued is performed via the inspection operation means, a predetermined second inspection for the external device different from the first alarm output is performed. Inspection control means for causing the alarm output means to perform the alarm output of No. 2 ,
The alarm output means is a voltage output means for performing a voltage output to the external device,
The voltage output means is
During normal times when no abnormality is detected in the monitoring area, a voltage output is performed using the first voltage,
When a predetermined abnormality is detected in the monitoring region, a voltage output is performed using a second voltage different from the first voltage,
The inspection control means includes
When the first inspection instruction is performed via the inspection operation means, the voltage output means according to the second voltage as the first alarm output,
When the second inspection instruction is performed via the inspection operation means, the voltage output means according to the first voltage is caused to perform a voltage output by the first voltage as the second alarm output.
Alarm, characterized in that. The alarm device is a gas leak alarm device that performs an alarm by detecting a gas leak in the monitoring area as the abnormality occurrence,
The voltage output means is the external device that does not cut off the gas supply when a voltage output by the first voltage is received, and supplies the gas when the voltage output by the second voltage is received. A voltage output is performed on the external device to be shut off
The alarm device according to claim 1. The inspection control means includes
If the inspection operation means is operated within a predetermined time after powering on the alarm device, it is determined that the first inspection instruction has been performed,
When the inspection operation means is operated after a lapse of a predetermined time after powering on the alarm device, it is determined that the second inspection instruction has been performed.
The alarm device according to claim 1, wherein the alarm device is provided. The inspection control means includes
If the inspection operation means is operated within a predetermined time after the occurrence of abnormality in the monitoring area is detected, it is determined that the first inspection instruction has been performed.
The alarm device according to any one of claims 1 to 3, wherein: The alarm device is a fire gas leak alarm device that performs an alarm by detecting a gas leak and a fire occurrence in the monitoring area as the abnormality occurrence,
A fire interlocking signal transmission / reception control means for transmitting / receiving an interlocking signal to / from a fire alarm device that detects a fire occurrence in the monitoring region as the abnormality occurrence and issues an alarm,
The inspection control means includes
When an instruction for interlocking inspection is made via the inspection operation means, the fire interlocking signal transmission / reception control means is made to output the interlocking signal to the fire alarm device,
The alarm device according to claim 1. The alarm is a fire alarm that performs an alarm by detecting the occurrence of a fire in the monitoring area as the abnormality occurrence,
A fire interlocking signal transmission / reception control means for transmitting / receiving an interlocking signal to / from a fire gas leak alarm device that detects and detects a gas leak and a fire occurrence in the monitoring region as the occurrence of an abnormality,
The inspection control means includes
When an instruction for interlocking inspection is made via the inspection operation means, the fire interlocking signal transmission / reception control means is made to output the interlocking signal to the fire gas leak alarm device.
The alarm device according to claim 1.

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