JP2016194836A - Alarm system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an alarm system that causes light emitting to be surely synchronized by curbing variations in a light emitting cycle when implementing a light emitting control on the basis of the clock count without requiring a timer reset and the like by means of communication during implementation of the light emitting control.SOLUTION: An optical alarm control device 30 is configured to periodically transmit a reference telegraphic message including current time information via a prescribed reference time interval twice, and an optical alarm device 32 is configured to: set the current time information obtained by reception of the reference telegraphic message to own current time information to update the own current time information; detect a reception time interval of the two-time reference telegraphic message to obtain a difference between the reception time interval and the reference time interval as a correction value; and correct the own current time information in accordance with the correction value to implement a light emitting control. The optical alarm control device 30 is configured to: transmit a control telegraphic message including control start time information by a fire alarm, and the optical alarm device 32 is configured to set light emitting schedule time information every time a light emitting cycle goes by on the basis of the control start time information; and emit a light emitting unit every time the current time information matches the light emitting schedule time information.SELECTED DRAWING: Figure 1

Description

  The present invention provides an alarm system that, when a fire alarm of a fire detector is received by a receiver, notifies the occurrence of a fire by flashing light by wirelessly transmitting a control message from a receiver side to a light alarm device in a warning area. About.

  Conventionally, in buildings such as office buildings, store buildings, hospitals, hotels, etc., an automatic fire alarm system has been used as an alarm system for monitoring the fire and notifying people in the building when a fire occurs. Is installed. In such an automatic fire alarm system, it is common to notify the occurrence of a fire by sound such as a buzzer, a bell, and a message. In addition to this sound notification, display notification using an LED, a red lamp, or the like is also performed as appropriate.

  By the way, in recent years, there has also been proposed an alarm system for notifying the occurrence of a fire by blinking high-luminance white light (flash light) having high visibility along with sound (for example, see Patent Documents 1 to 3). . According to such an alarm system, since the occurrence of a fire is notified not only by sound but also by flashing of strong light, for example, a hearing-impaired person can recognize the occurrence of a disaster early and reliably.

  A wireless alarm system has also been proposed in order to reduce the labor and cost of wiring (for example, see Patent Document 4). The wireless alarm system outputs a fire signal to the repeater via the electrical circuit and receives an alarm command signal (control message) from the repeater when the fire alarm is received by the fire receiver. Send to device. The optical alarm device includes a timer, and when the alarm command signal is received, the timer is reset and clock counting is started. When the count value reaches a predetermined delay time Δt, the light emitting unit is driven to emit light. Light emission is repeated while resetting the timer at period T. In addition, for an optical alarm device installed in a place where radio waves do not reach, a radio wave repeater is provided on the way to relay the alarm command signal.

  When the radio repeater receives the alarm command signal from the repeater connected to the fire receiver, it relays the alarm command signal when the period T has elapsed due to the clock count of the timer. When the command signal is received, the timer is reset and started, and when the count value reaches a predetermined delay time Δt, the light emitting unit is driven to emit light. As a result, although there is a time lag in the first light emission depending on the presence or absence of relaying, when all the light alarm devices start light emission, synchronized light emission is performed with a period T, and light sensitivity due to light emission at disjoint timing Make it possible to eliminate seizure problems.

  In addition, the repeater connected to the fire receiver transmits an alarm command signal at a predetermined cycle that is an integral multiple of the light emission cycle while the fire signal is being obtained. By resetting, the timer error due to the clock count is suppressed.

Utility Model Registration No. 3113946 JP 2005-165740 A JP 2011-198194 A JP 2014-186430 A

  However, in a conventional wireless alarm system that performs such an optical alarm, the internal timer provided in the repeater, radio wave repeater, and optical alarm device is reset by periodically sending an alarm command signal. However, even if the internal timer is reset repeatedly, the clock used for counting the internal timer varies depending on the device. There is a problem that becomes inconsistent.

  In order to solve this problem, it is conceivable to shorten the reset interval of the internal timer by transmitting an alarm command signal. However, if this is done, the number of communications increases, and radio relays operating on battery power The power consumption of the light alarm device may increase, and the battery may run out during the synchronized light emission of the light alarm based on the fire alarm.

  The present invention provides an alarm system that can reliably synchronize light emission by suppressing variations in the light emission cycle when performing light emission control based on clock count without requiring a timer reset by communication during light emission control. The purpose is to do.

(Alarm system)
The present invention
A receiver that detects a fire alarm of a fire detector and outputs a fire alarm;
A light alarm control device that transmits a control message including predetermined control start time information when a control signal for controlling a light alarm is received from a receiver; and
When a control message is received, the scheduled light emission time information is set every time a predetermined light emission period elapses based on the control start time information, and the current time information generated by itself matches the planned light emission time information. And a light alarm device for performing light emission control to emit light from the light emitting unit,
In the alarm system with
The light alarm control device transmits a reference message including current time information twice at predetermined intervals with a predetermined reference time interval.
The light alarm device sets the current time information obtained by receiving the reference message as its current time information, and detects the time interval from the reception of the first reference message to the reception of the next reference message. Thus, the difference from the reference time interval is obtained as a correction value, and the light emission control is performed by correcting the current time information generated by itself with the correction value.

(Correction of time counter value by clock count 1)
The light warning control device and the light warning device generate a time count value (Nt) indicating current time information by repeating counting of a clock with a predetermined frequency in a predetermined time unit,
The optical alarm device detects a time interval from the reception of the first reference message to the reception of the next reference message as a time interval count value (N) based on clock counting, and a reference time interval corresponding to the reference time interval The difference (ΔN) from the count value (Nr) is obtained as a correction value, and its own time count value (Nt) is determined as Nt ′ = Nt (1 + ΔN / Nr)
As a correction.

(Correction of time counter value by clock count 2)
When the optical warning device receives the first reference message, it stores the reference time count value (Nr1) and its own time count value (Nt1) included in the reference message, and also receives the next reference message. In this case, the reference time count value (Nr2) and the own reception time count value (Nt2) included in the reference message are stored,
When the first reference message is received and then the next reference message is received, the time interval (Nr2-Nr1) of the reference time count value is divided by the time interval (Nt1-Nt2) of its own time count value to obtain a correction coefficient ( α)
The self time count value (Nt) is expressed as Nt ′ = Nr1 + α (Nt−Nt1)
Or
Nt ′ = Nr2 + α (Nt−Nt2)
As a correction.

(Light emission control by clock count)
The light alarm device uses the light emission cycle as a light emission cycle count value (Nf) based on clock counting, and the control start time information as a start time count value (Na). As a light emission scheduled time count value (Ni) indicating Ni = (Na + i · Nf)
However, an integer indicating the number of times of light emission where i = 1, 2, 3,... Is set, and each time the corrected time count value (Nt) matches the scheduled light emission time count value (Ni), the light emitting unit is turned on. Performs light emission control.

(Fire alarm and control message transmission at inspection)
When receiving a control signal based on a fire alarm or a control signal based on an inspection operation of the receiver, the light alarm control device transmits a control message including control start time information.

(Relay control of standard message)
The light alarm control device relays the reference message when the reference message is transmitted twice with a reference time interval and no confirmation response messages are received from all destinations registered in advance. Send an instruction message,
When receiving a relay instruction message, the optical alarm device transmits a reference message including its current corrected time information twice with a reference time interval, and sets and corrects the time information to the relay destination optical alarm device. To do.

(Relay control of control message)
After transmitting a control message instructing light emission control, the light alarm control device transmits a relay instruction message when confirmation response messages from all the destinations registered in advance are not received,
When receiving a relay instruction message during light emission control, the light alarm device generates and relays a relay control message including predetermined control start time information.

(Continuous transmission and intermittent reception)
The light warning control device sets a transmission cycle (T0) consisting of a predetermined transmission time (T1) and a transmission suspension time (t2) a plurality of times, and repeats transmission of a message a plurality of times during each transmission time,
The light alarm device performs predetermined control based on information included in a telegram received first by intermittent reception.

(Basic effect of alarm system)
The present invention provides a receiver that detects a fire alarm of a fire detector and outputs a fire alarm, and a control message including predetermined control start time information when a control signal for controlling a light alarm is received from the receiver. When the control message is received and the light alarm control device that transmits the current time information that is generated by itself by setting the light emission scheduled time information every time a predetermined light emission cycle elapses based on the control start time information In an alarm system provided with a light alarm device that performs light emission control that emits light from the light emitting unit each time the light emission scheduled time information matches, the light alarm control device includes current time information for each predetermined period. The reference message is transmitted twice with a predetermined reference time interval, and the light alarm device sets the current time information obtained by receiving the reference message as its current time information and receives the first time reference message. The next time reference message Since the time interval until reception is detected and the difference from the reference time interval is determined as a correction value, the current time information generated by itself is corrected with the correction value to perform light emission control. The current time of the functioning relay control device can be set to all the light alarm devices and time synchronization can be established, and multiple light alarm devices internally generate time information by clock counting, so that time synchronization An error occurs when the time from the end of the time, but the internal error is eliminated in order to obtain a correction value for correcting the internal error from the reception of the reference message twice, and to correct the current time generated by itself. Thus, it is possible to maintain almost perfect time synchronization.

  As described above, since a plurality of light alarm devices are almost completely synchronized in time, when the light emission control is performed at a predetermined cycle based on the control start time corresponding to the alarm time based on the control message by the fire alarm, the light emission period Therefore, accurate synchronized light emission is possible without requiring reset in telegram communication during light emission control.

(Effect of current time correction 1 by clock count)
The light warning control device and the light warning device generate a time count value (Nt) indicating current time information by repeating counting of a clock with a predetermined frequency in a predetermined time unit,
The optical alarm device detects a time interval from the reception of the first reference message to the reception of the next reference message as a time interval count value (N) based on clock counting, and a reference time interval corresponding to the reference time interval The difference (ΔN) from the count value (Nr) is obtained as a correction value, and its own time count value (Nt) is determined as Nt ′ = Nt (1 + ΔN / Nr)
Therefore, even if there is a clock error inherent in the optical alarm device, this error is resolved and an accurate current time is generated in each of the multiple optical alarm devices, and the time synchronization is almost completely performed. It is possible to take.

(Effect of current time correction 2 by clock count)
Further, when the optical warning device receives the first reference message, it stores the reference time count value (Nr1) and its own time count value (Nt1) included in the reference message, and also stores the next reference message. When receiving, when the reference time count value (Nr2) and its own reception time count value (Nt2) included in the reference message are stored, the first reference message is received and then the next reference message is received Dividing the time interval of the reference time count value (Nr2-Nr1) by the time interval (Nt1-Nt2) of its own time count value to obtain the correction coefficient (α),
The self time count value (Nt) is expressed as Nt ′ = Nr1 + α (Nt−Nt1)
Or
Nt ′ = Nr2 + α (Nt−Nt2)
Therefore, even if there is a clock error inherent in the optical alarm device, this error is resolved and an accurate current time is generated in each of the multiple optical alarm devices, and the time synchronization is almost completely performed. It is possible to take.

(Effect of light emission control by clock count)
Further, the light alarm device is configured to emit light every time a predetermined light-emission period elapses when the light-emission period is a light-emission period count value (Nf) based on clock counting and the control start time information is a start time count value (Na). Ni = (Na + i · Nf) as a light emission scheduled time count value (Ni) indicating time information
However, an integer indicating the number of times of light emission where i = 1, 2, 3,... Is set, and each time the corrected time count value (Nt) matches the scheduled light emission time count value (Ni), the light emitting unit is turned on. Due to the emission control that emits light, the current time that is almost completely time-synchronized among multiple light alarm devices is the scheduled start time scheduled from the control start time corresponding to the fire alarm and the light emission cycle. By performing the light emission control every time the value reaches, even if there is a clock error inherent in the light alarm device, this error is eliminated and synchronized light emission with an accurate light emission cycle is enabled.

(Effects of fire alarm and transmission of control message during inspection)
In addition, the light alarm control device transmits a control message including control start time information when receiving a control signal based on a fire alarm or a control signal based on a check operation of the receiver from the receiver. Not only when a notification is detected, but also when an operation for inspection is performed at the operation unit of the receiver, the light emission control is performed so that the synchronized light emission of the light alarm can be confirmed.

(Effects of relay control of standard messages)
In addition, the optical warning control device instructs the relay of the reference message when the reference message is transmitted twice with a reference time interval and no confirmation response messages are received from all the registered destinations. When the relay instruction message is received, the optical alarm device transmits the reference message including the current time information corrected by itself twice with a reference time interval, and the relay destination optical alarm Since the time information is set and corrected by the device, the current time information can also be set by relaying the reference message for the light alarm device located at a remote location where the reference message from the light warning control device does not reach directly. And time synchronization by correction can be performed reliably.

(Effects of relay control of control messages)
In addition, after transmitting a control message instructing light emission control, the light alarm control device transmits a relay instruction message when confirmation response messages from all destinations registered in advance are not received. When the relay instruction message is received during the light emission control, the relay control message including the predetermined control start time information is generated and relay-transmitted. The light alarm device at the position can also be surely synchronized with light emission by relay transmission of a message.

(Effects of continuous transmission and intermittent reception)
The light alarm control device sets a transmission cycle (T0) consisting of a predetermined transmission time (T1) and a transmission suspension time (T2) a plurality of times, and repeats transmission of a telegram a plurality of times during each transmission time. Since the predetermined control is performed based on the information included in the first message received by intermittent reception, even if the light alarm device performs intermittent reception, the message is continuously transmitted multiple times from the light alarm control device. By doing so, it is possible to reliably receive a message and perform time synchronization and light emission synchronization reliably.

The block diagram which showed embodiment of the warning system which performs optical warning control by radio | wireless communication of a control message | telegram Block diagram showing the functional configuration of the light alarm control device Circuit diagram showing control message format Block diagram showing the functional configuration of the light alarm device Time chart showing time correction control in a light alarm device by receiving a reference message Time chart showing light emission control by transmission of control message Time chart showing light emission control when relaying control message following FIG. Time chart showing reference message transmission Time chart showing relay transmission of reference message following FIG. Flow chart showing control of light alarm control device Flow chart showing time correction control in light alarm device Flow chart showing light emission control in light alarm device Time chart showing another embodiment of time correction control in a light alarm device by receiving a reference message The flowchart which showed the time correction control of FIG.

[Alarm system]
(Alarm system configuration)
FIG. 1 is a block diagram showing an embodiment of a warning system that performs light warning control by wireless communication of electronic messages.

  As shown in FIG. 1, the alarm system of the present embodiment is an example of a P-type automatic fire alarm system, and a plurality of sensor lines 12 serving as power supply signal lines are provided from the fire receiver 10 toward a warning area. A plurality of fire detectors 14 are connected by pulling out the line, and a termination device (termination resistor) 16 is connected to the end of the line.

  The fire receiver 10 includes a reception control unit 20, and a line reception unit 22, a display unit 24, an operation unit 25, an alarm unit 26, and a transfer unit 28 are provided for the reception control unit 20.

  The reception control unit 20 is a function realized by executing a program, for example, and uses, as hardware, a computer circuit having a CPU, a memory, various input / output ports, and the like.

  The line receiving unit 22 supplies a predetermined DC voltage, for example, DC 24 volts as a power supply voltage to the fire detector 14 from a power source built in the fire receiver 10. The line receiver 22 detects the alarm current flowing through the sensor line 12 when the fire detector 14 detects a fire, and outputs a line current detection signal to the reception controller 20, and the reception controller 20 receives the line receiver 22. The fire alarm is determined by detecting that the line current detection signal from the terminal becomes equal to or higher than a predetermined fire alarm level.

  In addition, a predetermined line monitoring current determined by the terminating device 16 flows in the sensor line 12 in the normal monitoring state (non-reporting state). When the sensor line 12 is disconnected, the line monitoring current does not flow, and the reception control unit 20 detects a disconnection failure by detecting that the line current detection signal from the line receiver 22 has dropped below a predetermined value.

  The display unit 24 is provided with a fire representative lamp, a district display lamp, and other various display lamps and a liquid crystal display necessary for fire monitoring. The operation unit 25 is provided with various switches necessary for fire monitoring, such as a main sound stop switch, a district sound stop switch, a message stop switch, and an inspection switch. The alarm unit 26 includes a buzzer and a speaker, and outputs an acoustic alarm and a message alarm. The transfer unit 28 outputs a fire transfer signal to other devices.

(Light alarm control function)
The configuration and function of such an automatic fire alarm system are the same as those of the conventional system. In addition, in this embodiment, the light alarm control device 30 is arranged outside the fire receiver 10 and moved. A report signal line is connected from the report unit 28, and a wireless light alarm device 32 is arranged in the warning area. The function of the light alarm control device 30 may be provided inside the fire receiver 10.

  When the light alarm control device 30 receives a control signal (transmission control signal) for controlling the light alarm based on the detection of the fire alarm or the detection operation from the signal transmission unit 28 of the fire receiver 10, the light alarm control is performed. A control telegram for instructing is generated and wirelessly transmitted to the light alarm device 32 to perform light alarm control.

  The light alarm control device 30 includes the control start time information corresponding to the fire alarm or inspection operation in the transmitted control message, and the light alarm device 32 that receives the control message receives the control start obtained from the received control message. Based on the time information, the light emission scheduled time information is set every time a predetermined light emission cycle elapses, and the light emission control for emitting light from the light emitting unit is performed every time the current time information generated by itself matches the light emission scheduled time information. .

  In the following description, the time information is time, the count value of the clock count corresponding to the time information is the time count value, and the count value may be used as the time information.

  In addition, the light alarm control device 30 transmits a reference message including current time information twice at a predetermined reference time interval, for example, 10 seconds, in response to a predetermined time calibration cycle in a normal monitoring state. Then, the light alarm device 32 sets and updates the current time information obtained by receiving the reference message to its own current time information, and from receiving the first reference message to receiving the next reference message. The time interval is detected, the difference from the reference time interval is obtained as a correction value, and the current time information generated by itself is corrected by the correction value.

  The transmission of the reference message and the control message by the light warning control device 30 corresponds to the intermittent reception of the light warning device 32, and repeats a transmission cycle T0 composed of a predetermined transmission time T1 and a transmission pause time T2 a plurality of times. A message is continuously transmitted a plurality of times during time T1.

  The light warning device 32 receives the control message transmitted from the light warning control device 30, and white light or red light having a predetermined light intensity corresponding to the installation location by light emission control of the light emitting unit using a high-intensity LED, a flashlight, or the like. Light flashes and performs a light alarm to notify the occurrence of a fire with the flashing light.

  The flashing frequency of the light alarm by the light alarm device 32 is 0.5 Hz or more and 2 Hz or less, that is, the light emission period Tf is 0.5 or more and 2.0 seconds or less, and the light emission pulse width Tw is 0.2 seconds (200 ms). I do not exceed it.

  Further, the optical alarm device 32 performs intermittent reception for performing carrier sense at every predetermined intermittent reception cycle. When the transmission radio wave from the optical alarm control device 30 is detected by carrier sense, the optical alarm device 32 is switched to continuous reception. The electronic message transmitted from 30 is received, and time correction control and light emission control are performed based on the content of the received electronic message.

  In addition, the light warning control device 30 and the light warning device 32 are preliminarily assigned IDs serving as unique identification information.

  In addition, the optical warning control device 30 transmits the reference message or the control message, and if it does not receive the confirmation response message ACK from all the light warning devices 32 specified by the registered ID, the reference message is received. Alternatively, a relay instruction message for instructing relay transmission of the control message is generated and transmitted. In response to this, when receiving a relay instruction message from the light alarm control device 30, the light alarm device 32 generates and transmits a relay reference message or a relay control message.

(Configuration of light alarm control device)
FIG. 2 is a block diagram showing a functional configuration of the light alarm control device provided in FIG. As shown in FIG. 2, the light alarm control device 30 includes a control unit 34, a transmission input unit 36 to which a transmission signal line is connected and a communication unit 38 to which an antenna 40 is connected, and a power source from the fire receiver 10. Or it operates with a dedicated power supply.

  The control unit 34 of the light alarm control device includes a CPU 42 and a clock generation unit 44 as hardware, and also includes a memory and various input / output ports (not shown), and functions realized by execution of programs by the CPU 42. It is.

  The transfer input unit 36 detects an input of a control signal for controlling a light alarm based on detection of a fire alarm from the reception control unit 20 of the fire receiver 10 shown in FIG. Is output. Moreover, the input of the control signal which controls the light alarm output when the inspection operation by the operation part 25 of the fire receiver 10 is detected by the reception control part 20 is detected, and similarly, the control part 34 of the light alarm control apparatus. Outputs a light control signal.

  The communication unit 38 of the light alarm control device transmits / receives a message to / from the light alarm device 32 installed in the warning area. For example, in the case of Japan, the communication unit 38 performs wireless communication according to the standard of a specific low-power wireless station in the 400 MHz band, and has 48 channels having a band of 12.5 KHz from 426.2500 MHz to 426.8375 MHz. Either of the above can be used.

  Prior to the start of operation of the alarm system, the control unit 34 of the optical alarm control device registers in advance the identification information ID of all the optical alarm devices 32 that are communication destinations in its own memory.

  When the control unit 34 of the light warning control device detects the input of the light warning control signal from the transfer input unit 36, the control unit 34 generates a control message for performing light control, and the communication unit 38 of the light warning control device. Control to transmit to

  Here, the message transmitted from the light alarm control device has a signal format shown in FIG. 3, for example. As shown in FIG. 3, the control message includes a start code, a transmission source ID, a communication control code, control contents, time information, and a checksum. The size of the message is about 100 bits.

  In addition, the control unit 34 of the light warning control device generates a time count value Nt indicating the current time by repeating counting of clocks of a predetermined frequency output from the clock generation unit 44 of the light warning control device, for example, in units of 24 hours. ing. For example, taking a count of 1 second clock as an example, a time count value Nt in units of 24 hours repeats a count value of Nt = 0 to 86400. Further, the time count value can be converted into hour, minute and second as required.

  Note that the current time information generated by the control unit 34 of the light alarm control device is not standard time (Japan Standard Time) but relative time information by, for example, a 24-hour clock function. Of course, it may be adjusted to Japanese standard time if necessary. The clock function is not limited to 24 hours, and may be a 12-hour clock or a 6-hour clock. This also applies to the clock function of the light alarm device 32 that will be clarified later.

  In addition, when the light alarm control signal from the message input unit 36 is detected, the control unit 34 of the light alarm control device sets a transmission cycle T0 including a predetermined transmission time T1 and a transmission pause time T2 a plurality of times, for example, three times. Set and repeat the transmission of the control message a plurality of times during each transmission time T1, for example, the transmission of four control messages D1 to D4, D5 to D8, D9 to D12 divided into three times and start the light emission control The control start time count value Ns corresponding to the control start time indicating the time is set and transmitted to the time information, and the light alarm device 32 is controlled based on the control start time count value Ns included in the received control message. The light emission with the light emission period Tf is repeated.

  Here, the start time count value Ns indicating the control start time set in the time information of the control message is not the time when the fire alarm is detected by the fire receiver 10, for example, the control unit 34 of the light alarm control device controls the control message. A time count value indicating current time information for starting transmission of is set.

  In addition, after transmitting the control message, the control unit 34 of the light alarm control device compares the registration ID with the transmission source ID of the confirmation response message, and sends a confirmation response message ACK from all the transmission destinations for the transmission of the control message. When it is determined not to receive, control is performed to transmit the relay instruction message RC instructing the relay transmission of the control message, and the relay control message is generated and relayed to the light alarm device 32 that is receiving the light control. Send it.

  Further, the control unit 34 of the light alarm control device sets a reference telegram in which a time count value Nt indicating the current time is set to a predetermined reference interval Tr, for example, Tr = 10 seconds, every time a predetermined time calibration period is reached. Transmitting it twice, letting the light alarm device 32 perform time correction control.

  Also for the transmission of this reference message, the control unit 34 of the light alarm control device sets a transmission cycle T0 composed of a predetermined transmission time T1 and a transmission suspension time T2 a plurality of times, for example, twice, and between each transmission time T1. Repeat sending the reference message multiple times.

  Further, the control unit 34 of the light alarm control device determines that the confirmation response message ACK is not received from all the transmission destinations for the transmission of the reference message by comparing the registration ID with the transmission source ID of the confirmation response message ACK. In this case, control is performed to transmit a relay instruction message RC for instructing relay transmission of the reference message, and the light alarm device 32 that has received the light is controlled to set the time count value Nt indicating the current time to the time. The message is relayed twice with a predetermined reference time interval Tr.

  In addition, the control unit 34 of the optical alarm control device instructs the communication unit 38 of the optical alarm control device to transmit a periodic notification message at every predetermined periodic notification time, and sends a confirmation response message ACK to all the optical alarms. If there is a light alarm device 32 that is judged normal when received from the device 32 and the confirmation response message ACK cannot be obtained, control is performed to output a failure alarm. In addition, when there is a light alarm device 32 that cannot obtain a confirmation response message ACK for a periodic notification message, the control unit 34 of the light alarm control device performs control to transmit a relay instruction message of a periodic notification instructing relay transmission, The transmission of the periodic notification message including the relay transmission makes it possible to receive confirmation response messages ACK from all the light alarm devices 32.

[Light alarm device]
(Configuration of light alarm device)
FIG. 4 is a block diagram showing a functional configuration of the light alarm device provided in FIG. As shown in FIG. 4, the light alarm device 32 includes a control unit 46, a communication unit 48 connected to an antenna 50, and a light emitting unit 52, and operates with a battery power source (not shown).

  The control unit 46 of the light alarm device 32 includes a CPU 54 and a clock generation unit 56 as hardware, and also includes a memory and various input / output ports (not shown), and functions realized by execution of programs by the CPU 54. It is.

  The communication unit 48 of the light alarm device 32 transmits / receives a message to / from the light alarm control device 30 and also transmits a message to another light alarm device installed in a place where radio waves from the light alarm control device 30 do not reach. Perform relay transmission. The communication unit 48 of the optical alarm device 32 performs wireless communication in accordance with the standard of a specific low power wireless station in the 400 MHz band, for example, in Japan.

  Further, the communication unit 48 of the light alarm device 32 performs intermittent reception in a normal monitoring state. The intermittent reception cycle by the communication unit 48 of the optical alarm device 32 is set to a predetermined cycle that is shorter than the transmission time T1 by the communication unit 38 of the optical alarm control device 30 of FIG. If it is possible to perform carrier sense, it is possible to receive a message from the light alarm control device 30 by switching to continuous reception.

  The light emitting unit 52 is provided with a high-brightness LED, a flashlight, and the like and a drive circuit thereof. When receiving a light emission instruction from the control unit 46, a predetermined light emission cycle Tf, for example, Tf = 2 seconds, for example, Tw = Repeated blinking for a light emission period of 200 milliseconds.

(Light emission control)
The control unit 46 of the light alarm device 32 generates a time count value Nt indicating the current time by repeating the counting of a clock with a predetermined frequency output from the clock generation unit 56 of the light alarm device 32, for example, in units of 24 hours. .

When the control unit 46 of the light alarm device 32 detects reception of a control message from the light alarm control device 30 via the communication unit 48 of the light alarm device 32, the control set in the time information of the control message. A control start time count value Ns indicating the start time is acquired, and a light emission scheduled time count value Npi indicating a light emission scheduled time is obtained as follows based on the light emission cycle count value Nf corresponding to the light emission cycle Tf.
Npi = Ns + i · Nf (1)
However, the integer indicating the number of times of light emission where i = 1, 2, 3,... The control unit 46 of the light alarm device 32 emits the time count value Nti indicating the current time generated by itself. When it coincides with the scheduled time count value Npi, control is performed to cause the light emitting unit 52 to emit light, thereby causing the light emitting unit 48 to repeat the light emission driving for each light emission period Tf and perform an operation of notifying a light alarm by blinking light.

  Further, when the control unit 46 of the light alarm device 32 receives the control message and starts the light emission control, the control unit 46 instructs the communication unit 48 to transmit the confirmation response message ACK. Here, the transmission timing of the confirmation response message ACK has a different delay time corresponding to the ID of the light alarm device 32 and the like, and collision of confirmation response messages ACK from a plurality of light alarm devices 32 can be avoided. .

  Further, the control unit 46 of the light alarm device 32 detects reception of the relay instruction message RC from the light alarm control device 30 via the communication unit 48 of the light alarm device 32 during the light emission control based on reception of the control message. In this case, the communication unit 48 of the light alarm device 32 is instructed, the transmission cycle T0 composed of the transmission time T1 and the transmission pause time T2 is set, for example, three times, and the transmission of the relay control message R is transmitted, for example, four times during each transmission time T1. Repeat once.

  In the time information of the relay control message R, a control start time count value Ns indicating the control start time is set as in the case of the control message. For this reason, the optical warning device 32 of the relay destination that has received the relay control message obtains the scheduled light emission time count value Npi based on the control start time count value Ns included in the relay control message R that has been effectively received first by intermittent reception. When the time count value Nti indicating the current time generated in (1) coincides with the light emission scheduled time count value Npi, light emission is performed and light emission according to the light emission cycle Tf is repeated.

(Time correction control)
FIG. 5 is a time chart showing the time correction control by the reception of the reference telegram in the light alarm device, FIG. 5 (A) shows the reception of the reference telegram, and FIG. 5 (B) shows the clock counting operation of the internal timer. Show.

  As shown in FIG. 5 (A), the light alarm device 32 shown in FIG. 4 has two times t1 and t2 with a reference time interval Tr from the light alarm control device 30 every predetermined time calibration period. The reference message is received separately.

The control unit 46 of the light alarm device 32 starts the internal timer by receiving the first reference message at time t1, starts counting the clock from the clock generation unit 56, and receives the next reference message at time t2. The count value N is obtained, and an error ΔN with respect to the reference time interval count value Nr indicating the reference time interval Tr is obtained by the following equation.
ΔN = Nr−N (2)
Here, as shown in FIG. 5B, when there is no error in the count of the internal timer, the change is shown by a straight line 60. On the other hand, when the clock cycle is shifted to the longer side, the change is positive as shown by a straight line 62. The correction value −ΔN is obtained. On the other hand, when the clock cycle is shifted to the shorter side, a negative error ΔN is obtained as indicated by a straight line 64, and a correction value + ΔN is obtained. The straight lines 60, 62, and 64 actually change stepwise, but are omitted and shown as straight line changes.

Therefore, the control unit 46 corrects the time count value Nt indicating the current time generated by itself based on the correction value −ΔN or + ΔN, and generates a correct time count value Nt ′. Update the corrected time count value Nt ′ to the time count value Nt indicating the current time generated by itself Nt ′ = Nt (1 + ΔN / Nr) (3)
Further, the control unit 46 updates the time count value Nt set on the light alarm control device 30 side in the reference message received first, for example, to the time count value generated by itself, and updates the light alarm device 32. Is synchronized with the current time of the light warning control device 30, and as a result, the correct current time is generated by correcting the current time at which the time synchronization has been achieved by the equation (3). .

  By such time correction control, the current time of the light alarm control device 30 functioning as a master in the normal monitoring state can be set in all the light alarm devices 30, and time synchronization can be established. 32 generates the current time internally by counting the clock, and an error occurs when the time from the time synchronization elapses. A correction value for correcting the internal error is obtained from the reception of the reference message twice. Since the current time generated by itself is corrected, the internal error can be eliminated and substantially perfect time synchronization can be maintained.

  Furthermore, since the plurality of light alarm devices 32 are almost completely synchronized in time, when the light emission control is performed based on the reception of the control telegram by the fire alarm, the light emission period does not shift and the reset by the telegram communication is necessary. Thus, accurate light emission synchronization is possible.

[Light alarm control of alarm system]
FIG. 6 is a time chart showing light emission control by transmission of a control message, FIG. 6 (A) shows a fire alarm, FIG. 6 (B) shows message transmission by a light alarm control device, and FIG. ) Shows light emission control of the light alarm device, and FIG. 6D partially shows relay control of the light alarm device.

  FIG. 7 is a time chart showing light emission control when relay control is performed by transmitting a relay instruction message following FIG. 6, FIG. 7A shows a fire alarm, and FIG. ) Shows the message transmission by the light alarm control device, FIG. 7C shows the light emission control of the light alarm device, FIG. 7D shows the relay control of the light alarm device, and FIG. 7E shows the relay destination. The light emission control at is shown.

(Light alarm control by transmission of control message)
Assuming that a fire alarm is detected by the fire receiver 10 at time t0 in FIG. 6A and a fire alarm is output, a control signal for controlling the light alarm is given to the light alarm controller 30 from the transfer unit 28. Then, the transmission operation of the control message is started from time t1 in FIG.

  In the transmission operation of the light alarm control device 30, a transmission cycle T0 that is a combination of the transmission time T1 and the transmission suspension time T2 is set three times, and during each transmission time T1, control messages D1 to D4, D5 to D8, D9 to D12 are repeatedly transmitted.

  For example, taking the head control message D1 as an example, as the control start time, for example, the time count value indicating the time t0 when the light alarm control signal by fire alarm is received is set in the time information as the control start time count value Ns. Yes. Similarly, the control start time count value Ns is set for the remaining control messages D2 to D12.

The control telegrams D1 to D12 transmitted from the light alarm control device 30 are received by the light alarm device 32 shown in FIG. 1, and the light alarm device 32 receives the control start time count value Ns obtained from the received control telegram. Based on the light emission cycle count value Nf indicating the light emission cycle Tf, the light emission scheduled time count value Npi indicating the light emission scheduled time is set as follows.
Np1 = Ns + Nf
Np2 = Ns + 2Nf
Np3 = Ns + 3Nf
Np4 = Ns + 4Nf
Np5 = Ns + 5Nf
...
Since the light alarm device 32 performs intermittent reception, any one of the control telegrams D1 to D12 is received first, but even if any of the control telegrams D1 to D12 is received, the light emission scheduled time count value Npi Will set the same value. For this reason, for example, the one or more light alarm devices 32 that have received the control message D1 and set the scheduled light emission time count value Npi have the first time t2 when the time count value Nt matches the first light emission scheduled time count value Np1. Light is emitted, and then light is emitted at each light emission period Tf, such as times t2, t3, t5,..., And light emission by the plurality of light alarm devices 32 is synchronized.

(Light alarm control by telegram relay)
When the light alarm control device 30 ends the transmission of the control messages D1 to D12 in FIG. 6, for example, the confirmation response message ACK from the light alarm device 32 is received during the time t4 to t5. The light warning control device 30 collates the ID of the light warning device 32 obtained by receiving the confirmation response message ACK with the ID of the transmission destination registered in advance, and the confirmation response messages ACK are received from all the light warning devices 32. If it is determined that it has not been obtained, the relay instruction message RC is transmitted at time t5. The subsequent operation will be described with reference to FIG.

  As shown in FIG. 7B, the relay instruction message RC started to be transmitted by the light alarm control device 30 at the time t5 is the light alarm device 32 in FIG. The transmission of the relay control message Ri is started from the time t7 through the desired operation time Td necessary for the relay control after the reception of the relay instruction message RC at the time t6.

  As shown in FIG. 7D, this relay control message is also transmitted by setting a transmission cycle T0, which is a combination of the transmission time T1 and the transmission pause time T2, three times, and the relay control message R1 during each transmission time T1. To R4, R5 to R8, and R9 to R12 are repeatedly transmitted. Further, in each of the relay control messages R1 to R12, the time count value indicating the time t0 shown in FIG. 6 is set as the control start time count value Ns.

  The relay control messages R1 to R12 are received by the light alarm device 32 as the relay destination, and based on the control start time count value Ns and the light emission cycle count value Nf obtained from the received relay control message, the light emission scheduled time count value Npi is calculated. The light emission control is performed every time the time count value Nt matches the light emission scheduled time count value Npi. As a result, all the light alarm devices 32 including the relay destination perform synchronized light emission of the light alarm.

[Time correction control of alarm system]
FIG. 8 is a time chart showing time correction control by transmission of a reference message, FIG. 8A shows calibration timing, and FIG. 8B shows transmission of a reference message by a light alarm control device.

  FIG. 9 is a time chart showing time correction control when relay control is performed by transmitting a relay instruction message following FIG. 8, FIG. 9A shows calibration timing, and FIG. ) Shows message transmission by the light alarm control device, and FIG. 9C shows relay control of the light alarm device.

(Transmission of reference message)
When the light alarm control device 30 detects the calibration timing based on the predetermined time calibration period at the time t1 in FIG. 8A, as shown in FIG. 8B, the reference telegram is transmitted with a predetermined reference time interval Tr. The operation of transmitting twice is performed.

  The transmission operation of the light alarm control device 30 sets the transmission cycle T0, which is the sum of the transmission time T1 and the transmission suspension time T2 from time t1, and transmits the first reference telegrams K1 to K8. A reference cycle K9 to K16 is transmitted by setting the transmission cycle T0, which is a combination of the transmission time T1 and the transmission suspension time T2, from the time t7 when the time interval Tr has elapsed, and the reference is transmitted in two steps. Combinations of messages, that is, message pairs are (K1, K9), (K2, K10), (K3, K11), (K4, K12), (K5, K13), (K6, K14), (K7, K15). , (K8, K16).

  In the time information of the reference messages K1 to K16, a time count value Nt indicating the end point of message transmission and an identifier indicating the message pair are set.

  When the light alarm device 32 first receives the reference message K1, for example, as shown in FIG. 5B, the light alarm device 32 starts counting the clock by the internal timer from the reception end time t2 of the reference message K1, and the reference message K1 The clock count by the internal timer is stopped at the reception end time t8 when the paired reference telegram K9 is received, and the correction count value ΔN is based on the difference between the count value N and the reference time interval count value Nr obtained thereby. Is stored in the memory, and the time count value Nt indicating the current time generated by the light alarm device 32 is corrected according to the equation (3).

  The time correction control is performed in the same manner when any of the remaining pairs (K2, K10) to (K8, K16) of the reference message is received.

(Time correction control by telegram relay)
When the light warning control device 30 finishes transmitting the reference messages K1 to K16 in FIG. 8, for example, the confirmation response message ACK is received from the light warning device 32 from time t13. The light warning control device 30 collates the ID of the light warning device 32 obtained by receiving the confirmation response message ACK with the ID of the transmission destination registered in advance, and the confirmation response messages ACK are received from all the light warning devices 32. If it is determined that it has not been obtained, the relay instruction message RC is transmitted at time t14. The subsequent operation will be described with reference to FIG.

  As shown in FIG. 9B, the relay instruction message RC that has started transmission at time t14 is received by the light alarm device 32, and the desired operation time required for relay control from the end of reception of the relay instruction message RC is Td. After that, transmission of the relay reference message RSi (i = 1, 2, 3,...) Is started from time t15.

  As shown in FIG. 9C, the transmission of the relay reference message is also performed by setting a transmission cycle T0 that is a combination of the transmission time T1 and the transmission suspension time T2 twice from the time t15, and setting the first relay reference messages RK1 to RK8. The transmission period T0 that combines the transmission time T1 and the transmission suspension time T2 is set twice from the time t21 when the reference time interval Tr has elapsed from the time t15, and the next reference messages RK9 to RK16 are transmitted. Combinations of reference messages transmitted twice, that is, message pairs are (RK1, RK9), (RK2, RK10), (RK3, RK11), (RK4, RK12), (RK5, RK13), (RK6, RK14). , (RK7, RK15), (RK8, RK16).

  In the time information of the relay reference messages RK1 to RK16, a time count value Nt indicating the end point of the message transmission and an identifier indicating the message pair are set.

  For example, when the relay destination optical alarm device 32 receives the first relay reference message RK1, as shown in FIG. 5B, it counts the clock by the internal timer from the reception end time t16 of the relay control message RK1. The count of the clock by the internal timer is stopped at the reception end time t22 when the relay reference message RK9 that is paired with the relay reference message RK1 is received, and the count value N and the reference time interval count value Nr thus obtained are stopped. Based on the difference, the correction count value ΔN is acquired and stored in the memory, and the time count value Nt indicating the current time generated in the optical alarm device 32 at the relay destination is corrected according to the equation (3).

  When any one of the remaining pairs (RK1, RK9) to (RK8, RK16) of the relay reference message is received, the time correction control is performed in the same manner.

[Alarm system control action]
(Control operation of light alarm control device)
FIG. 10 is a flowchart showing the control operation of the light alarm control device. As shown in FIG. 10, when the control unit 34 provided in the light alarm control device 30 of FIG. 2 detects the arrival of the time calibration timing in step S1, the control unit 34 proceeds to step S2, and a reference message including the current time Nt is Transmit twice with a reference time interval Tr. Actually, a plurality of pairs of reference messages are continuously transmitted in two divided intervals with a reference time interval Tr.

  Subsequently, when reception of a control signal for controlling a light alarm based on detection of a fire alarm at the fire receiver 10 is detected in step S3, the process proceeds to step S4 to store the control start time Ns, and in step S5, the control start time. A control message including Ns and a light emission instruction is generated, and the control message is repeatedly transmitted, for example, divided into three transmission times.

  Then, it progresses to step S6, receives the confirmation response message | telegram ACK from the light warning apparatus 32, and when not receiving all the confirmation response message | telegram ACK, it progresses to step S7 and transmits the relay instruction | indication message | telegram RC.

  Thereafter, when reception of a control signal for stopping the light alarm is detected in step S8 based on a fire recovery or the like, the process proceeds to step S9 to transmit a control message including a stop instruction to stop the light alarm of the light alarm device 32.

(Control action of light alarm device)
FIG. 11 is a flowchart showing time correction control of the light alarm device. As shown in FIG. 11, the control unit 46 provided in the light alarm device 32 of FIG. When the reception of the first reference telegram is detected in step S11, the process proceeds to step S12, where the received time count value Nt is set and updated to the time count value generated by itself, and the clock count is started.

  Subsequently, when reception of the next reference message is detected in step S13, the process proceeds to step S14 to stop the clock count and acquire the count value N, and the process proceeds to step S15 to correct the difference ΔN from the reference time interval count value Nr. And store it in the memory.

  Subsequently, in step S16, the time count value Nt generated by itself is corrected by the correction value ΔN to generate a corrected time count value Nt ′. Such processes of steps S11 to S16 are repeated every time a reference message is received, and time synchronization with the light alarm control device 30 is established.

  FIG. 12 is a flowchart showing the control operation of the light alarm device. As shown in FIG. 12, the control unit 46 provided in the light alarm device 32 of FIG. 4 determines the presence or absence of carrier sense when detecting the arrival of the intermittent reception cycle, and switches to the continuous reception operation when determining carrier sense. When the reception of the control message is detected in step S21, the process proceeds to step S22 and the control start time Ns is acquired.

  Subsequently, in step S23, the scheduled light emission time Npi is generated based on the control start time Ns and the light emission cycle Nf. When it is detected in step S24 that the current time Nt has reached the light emission scheduled time Npi, the process proceeds to step S25 to emit light. The part is driven to emit light.

  Subsequently, an acknowledgment response message ACK is transmitted in step S26, and if reception of a relay instruction message is detected in step S27, the process proceeds to step S28, where a relay control message in which the control start time information Ns is set is generated and relayed.

  Until the reception of the stop control message based on the fire recovery or the like is detected in step S29, the processes in steps S21 to S24 are repeated to flash the light synchronized with the other light alarm devices 32, that is, to notify the light alarm by the synchronized light emission. Do. If reception of the stop control message is detected in step S29, the process proceeds to step S30 to stop the light emission control, and the process returns to step S21.

(Another embodiment of time correction control)
FIG. 13 is a time chart showing another embodiment of time correction control based on reception of a reference telegram in the light alarm device. FIG. 13A shows a time count value of the light alarm control device 30, and FIG. B) shows the transmission of the reference message, and FIG. 13 (C) shows the time count value of the light alarm device 32. Here, when the time count value of the light alarm control device 30 is set to the reference time count value Nr, and the time count value of the light alarm device 32 is set to Nt, and the time count value is distinguished, it is set to Nri or Nti (however, , I is an integer indicating the order).

  As shown in FIGS. 13A and 13B, the light alarm control device 30 shown in FIG. 1 has a reference time count value Nr1 indicating the current time with a predetermined reference time interval for each predetermined time calibration period. And a reference telegram including each reference time count value Nr2 is transmitted in two parts.

  When the control unit 46 of the light alarm device 32 shown in FIG. 4 receives the first reference message, the control unit 46 stores the reference time count value Nr1 included in the reference message in the memory, and also in FIG. The own time count value Nt1 at the time of receiving the indicated reference message is stored in the memory. Even when the next reference message is received, the reference time count value (Nr2) included in the reference message is stored in the memory, and the reception time of the self at the time of receiving the reference message shown in FIG. The count value Nt2 is stored in the memory.

Subsequently, the control unit 46 of the light alarm device 32 receives the first reference message and then receives the next reference message, the time interval (Nr2-Nr1) of the reference time count value and the time of its own time count value. The interval (Nt1-Nt2) is obtained, and between the correction coefficient (α) for matching the time interval (Nt1-Nt2) of its own time count value with the time interval (Nr2-Nr1) of the reference time count value,
(Nr2-Nr1) = α (Nt1-Nt2)
Therefore, the correction coefficient α is set to α = (Nr2−Nr1) / (Nt1−Nt2) (4)
Asking.

For this reason, the time count value Nt obtained thereafter is set to Nt ′ = Nr1 + α (Nt−Nt1) (5)
Or
Nt ′ = Nr2 + α (Nt−Nt2) (6)
Is corrected to a value that matches the time count value of the light alarm control device 30.

  By such time correction control, the current time of the light alarm control device 30 functioning as a master in the normal monitoring state can be set in all the light alarm devices 30, and time synchronization can be established. 32 generates the current time internally by counting the clock, and an error occurs when the time from the time synchronization elapses, but a correction coefficient for correcting the internal error is obtained from the reception of two reference telegrams. Since the current time generated by itself is corrected, the internal error can be eliminated and substantially perfect time synchronization can be maintained.

  In addition, since a plurality of light alarm devices 32 are almost completely synchronized in time, when light emission control is performed based on reception of a control telegram by fire alarm, there is no deviation in the light emission period, and reset by telegram communication is required. Thus, accurate light emission synchronization is possible.

  Furthermore, unlike the time correction control of FIG. 4, the light alarm device 32 does not require a clock count based on the reception of the reference telegram, so that the time correction control can be simplified accordingly.

(Control action of light alarm device)
FIG. 14 is a flowchart showing time correction control according to FIG. As shown in FIG. 14, the control unit 46 provided in the light alarm device 32 of FIG. When reception of the first reference message is detected in step S31, the process proceeds to step S32, and the reference time count value Nr1 and its own time count value Nt1 included in the reference message are stored in the memory.

  Subsequently, when reception of the next reference message is detected in step S33, the process proceeds to step S34, and the reference time count value Nr2 and the own time count value Nt2 included in the reference message are stored.

  Subsequently, the process proceeds to step S35 to obtain the correction coefficient α from the equation (3), and then proceeds to step S36 to correct the own time count value Nt by the equation (4) or the equation (5). The generated time count value Nt ′ is generated. Such processing of steps S31 to S36 is repeated every time a reference message is received, and time synchronization with the light alarm control device 30 is established.

  The light emission control by the time count value Nt ′ corrected by the time correction control of FIG. 14 is the same as that shown in the flowchart of FIG.

[Modification of the present invention]
In the above embodiment, a P-type fire receiver that monitors a fire in units of sensor lines is taken as an example. However, an R-type that monitors a fire in units of addresses by connecting a fire detector with an address set to a transmission line. It may be a fire receiver.

  The present invention includes appropriate modifications without impairing the object and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

10: Fire receiver 12: Sensor line 14: Fire detector 16: Termination device 20: Reception control unit 22: Line reception unit 24: Display unit 25: Operation unit 26: Alarm unit 28: Transfer unit 30: Light alarm Control device 32: Light alarm device 34, 46: Control unit 36: Transfer input unit 38, 48: Communication unit 42, 54: CPU
44, 56: Clock generator 52: Light emitting unit

Claims (8)

A receiver that detects a fire alarm of a fire detector and outputs a fire alarm;
A light alarm control device that transmits a control message including predetermined control start time information when a control signal for controlling a light alarm is received from the receiver;
When the control message is received, the scheduled light emission time information for each elapse of a predetermined light emission period is set based on the control start time information, and the current time information generated by itself is set as the light emission scheduled time information. A light alarm device that performs light emission control for emitting light from the light emitting unit every time they match,
In the alarm system with
The light alarm control device transmits a reference message including current time information twice at predetermined intervals with a predetermined reference time interval.
The light alarm device sets the current time information obtained by receiving the reference message as its current time information, and a time interval from receiving the first reference message to receiving the next reference message. And detecting the difference from the reference time interval as a correction value, and performing the light emission control by correcting the current time information generated by itself with the correction value.
The alarm system according to claim 1, wherein
The light warning control device and the light warning device generate a time count value (Nt) indicating current time information by repeating counting of a clock having a predetermined frequency in a predetermined time unit,
The light alarm device detects a time interval from the reception of the first reference message to the reception of the next reference message as a time interval count value (N) based on clock counting, and a reference time corresponding to the reference time interval. The difference (ΔN) from the interval count value (Nr) is obtained as a correction value, and its own time count value (Nt) is Nt ′ = Nt (1 + ΔN / Nr)
Alarm system characterized by correcting as.
The alarm system according to claim 1, wherein
When receiving the first reference message, the light alarm device stores the reference time count value (Nr1) and its own time count value (Nt1) included in the reference message, and receives the next reference message. The reference time count value (Nr2) and the own reception time count value (Nt2) included in the reference message are stored,
When the first reference message is received and then the next reference message is received, the time interval (Nr2-Nr1) of the reference time count value is divided by the time interval (Nt1-Nt2) of its own time count value to obtain a correction coefficient ( α)
The self time count value (Nt) is expressed as Nt ′ = Nr1 + α (Nt−Nt1)
Or
Nt ′ = Nr2 + α (Nt−Nt2)
Alarm system characterized by correcting as.
4. The alarm system according to claim 2, wherein the light alarm device uses the light emission cycle as a light emission cycle count value (Nf) based on the counting of the clock, and the control start time information as a start time count value (Na). In this case, Ni = (Na + i · Nf) as a light emission scheduled time count value (Ni) indicating information on the light emission scheduled time every time a predetermined light emission cycle elapses
However, an integer indicating the number of times of light emission where i = 1, 2, 3,... Is set, and light is emitted every time the corrected time count value (Nt) matches the light emission scheduled time count value (ni). An alarm system characterized by performing light emission control to emit light.
2. The alarm system according to claim 1, wherein the light alarm control device receives the control signal based on a fire alarm or the control signal based on an inspection operation of the receiver from the receiver. An alarm system characterized by transmitting a control message including information.
The alarm system according to claim 1, wherein
The light warning control device relays the reference message when the reference message is transmitted twice with the reference time interval and no confirmation response messages are received from all the destinations registered in advance. Send an instruction message,
When the light warning device receives the relay instruction message, the light warning device transmits a reference message including the current time information corrected by itself twice with the reference time interval, and transmits the time information to the relay destination light warning device. Alarm system characterized by setting and correction.
The alarm system according to claim 1, wherein
The light warning control device transmits a relay instruction message when confirmation response messages from all destinations registered in advance are not received after transmitting a control message instructing the light emission control,
The light alarm device generates and relays a relay control message including predetermined control start time information when the relay instruction message is received during the light emission control.
The alarm system according to claim 1, wherein
The light alarm control device sets a transmission cycle (T0) consisting of a predetermined transmission time (T1) and a transmission pause time (T2) a plurality of times, and repeats transmission of a telegram a plurality of times during each transmission time,
The light alarm device performs predetermined control based on information included in a telegram received first by intermittent reception.

Images