JP5881316B2 - Alarm system - Google Patents

Description

  The present invention relates to an alarm system that transmits and receives radio signals between a plurality of alarm devices.

  The fire alarm system as an example of the alarm system is composed of a plurality of fire alarms. When the fire alarm detects a fire, the alarm means notifies the fire and sends a radio signal to other fire alarms. On the other hand, the other fire alarm device receives the radio signal and notifies the fire by the notification means so that the fire can be notified in the entire system.

  Here, one of the plurality of fire alarms is set as a master unit, the remaining fire alarms are set as slave units, and the master unit is arranged so that all the plurality of slave units are included in the transmission range of the radio signal, Periodic monitoring is performed by periodically transmitting and receiving radio signals between the master unit and the slave unit, and the control unit of the master unit receives an interlock request signal including a notification message for notifying the occurrence of a fire by the receiving unit. Upon reception, all other slave units also send an interlocking command signal including a notification message for driving the notification unit from the transmission unit, and the slave unit control unit detects a fire with the fire detection unit of the slave unit. Then, after transmitting the interlock request signal from the transmitting unit of the slave unit, if the receiving unit of the slave unit receives the interlock command signal transmitted from the transmitting unit of the master unit, the transmitting unit of the slave unit Some stop transmission of the interlock request signal ( In example, see Patent Document 1).

Japanese Patent No. 4466792

  In the fire alarm system of Patent Document 1 above, if an alarm device other than the child device that detects the fire receives either the interlock request signal from the child device that detected the fire or the interlock command signal from the master device, The notification means can be driven.

  By the way, when multiple fire alarms detect an abnormality at the same time and send a signal (interlocking signal) containing a notification message to notify the occurrence of the abnormality, the other signals will collide with each other. Even if the device receives the interlocking signal, it cannot decipher, and as a result, the entire system cannot report the abnormality.

  The present invention has been made to solve the above problems, and in an alarm system having a parent alarm device and a child alarm device, even if a plurality of fire alarms detect an abnormality at the same time, A fire alarm provides an alarm system that can receive and decode an interlocking signal.

The present invention includes a state detection unit that detects an abnormality in the installation environment, a transmission / reception unit that transmits and receives radio signals, a notification unit that notifies that an abnormality in the installation environment is detected by the state detection unit, the transmission / reception unit, and the notification A plurality of alarm devices having a control unit for controlling the means, one of the plurality of alarm devices is a parent alarm device, the other alarm device is a child alarm device, the parent alarm device is a plurality of alarm devices The radio alarm transmission ranges of all the child alarm devices are arranged in an overlapping region, and the transmission / reception unit of the parent alarm device includes all of the plurality of child alarm devices within the radio signal transmission range, and the state detection unit detects an abnormality. Upon detection, the control unit of the parent alarm device drives the notification means of all other child alarm devices, and the control unit of the child alarm device drives the notification means of all other alarm devices, Each of the above-mentioned transmission / reception signals that notify the occurrence of an abnormality Alarm system for transmitting and receiving radio signals among the plurality of alarm devices after transmitting the interlock signal and after a predetermined pause period has elapsed, In the above, the suspension period of the child alarm device is set as a second suspension period that is individually set for all the child alarm devices, and is a different suspension time, and the suspension period of the parent alarm device is The first suspension period set to a predetermined time shorter than the second suspension period, and when a plurality of the alarm devices detect an abnormality at the same time and transmit interlocking signals, the re-transmission timing of each alarm device And the parent alarm device can retransmit the interlock signal in preference to the child alarm device.

  Further, the control unit of the child alarm device activates the reception function of the transmission / reception unit during the second pause period to perform carrier detection, and if a carrier is detected during the second pause period, The interlocking signal is not transmitted from the transmission / reception unit.

  In addition, the control unit of the alarm device activates the reception function of the transmission / reception unit and performs carrier detection only during a predetermined carrier sense period before starting transmission of the radio signal from the transmission / reception unit. If no carrier is detected during the period, the radio signal is transmitted from the transceiver, and the carrier sense period is set to a predetermined time longer than the first pause period and the second pause period. It is characterized by being.

  In addition, when the control unit of the parent alarm device receives the interlock signal transmitted from the child alarm device, after the transmission period of the interlock signal ends, the notification unit of all other child alarm devices is driven. In order to make it possible, the interlock transfer signal is transmitted to all the other child alarm devices, and the control unit of the child alarm device transmits the interlock transfer transmitted from the parent alarm device within the second pause period. When the signal is received, the interlock signal is not transmitted from the transmission / reception unit.

  The present invention includes a state detection unit that detects an abnormality in the installation environment, a transmission / reception unit that transmits and receives radio signals, a notification unit that notifies that an abnormality in the installation environment is detected by the state detection unit, the transmission / reception unit, and the notification A plurality of alarm devices having a control unit for controlling the means, one of the plurality of alarm devices as a parent alarm device, the other alarm device as a child alarm device, between the plurality of alarm devices In the alarm system for transmitting and receiving radio signals, the parent alarm device is disposed in a region where the transmission ranges of the radio signals of all of the plurality of child alarm devices overlap, and the transmission / reception unit of the parent alarm device includes all of the plurality of child alarm devices. Within the transmission range of the radio signal, and when the state detector detects an abnormality, the control unit of the parent alarm device notifies the occurrence of the abnormality in order to drive the notification means of all other child alarm devices Other link signals from the transceiver After transmission of the interlocking signal is completed and the first suspension period of a predetermined time has elapsed, the interlocking signal is transmitted from the transmitting / receiving unit to all the other alarm alarms. When the state detection unit detects an abnormality, the control unit of the child alarm device transmits an interlock signal that notifies the occurrence of the abnormality to drive the notification means of all other alarm devices, After the transmission / reception unit transmits to all other alarm devices, the transmission of the interlocking signal ends, and after a second pause period of a predetermined time has elapsed, the interlocking signal is transmitted from the transmission / reception unit to all other The first suspension period is set to a predetermined time shorter than the second suspension period, and the second suspension period is individually set for all the child alarm devices. It is a predetermined time set in (1). When a plurality of alarm devices detect an abnormality at the same time and transmit an interlocking signal, the signals collide with each other, so that other alarm devices cannot be deciphered even if they receive the interlocking signal. However, the parent alarm device ends the transmission of the interlocking signal and the first suspension period of the predetermined time elapses, and the child alarm device completes the transmission of the interlocking signal and the second suspension of the predetermined time. After the period has elapsed, the interlocking signal is retransmitted. Here, the first suspension period and the second suspension period are individually set for each alarm device, so when transmitting the interlocking signal again, Since the re-transmission timing of each alarm device is different and a location where each interlocking signal does not collide occurs, another alarm device can receive the signal at the location where the interlock signal does not collide and decode the signal. In particular, since the first suspension period is set to a predetermined time shorter than the second suspension period, the parent alarm device capable of transmitting a signal to all the child alarm devices is a child alarm device due to the arrangement. As a result, the interlocking signal can be retransmitted with higher priority, and the probability that all alarm devices can receive the interlocking signal quickly can be increased.

  Further, the control unit of the child alarm device activates the reception function of the transmission / reception unit during the second pause period to perform carrier detection, and if a carrier is detected during the second pause period, Since the interlocking signal is not transmitted from the transmitting / receiving unit, the interlocking signal is transmitted from only one alarm device, so that no signal collision occurs. For this reason, the other alarm devices can reliably receive the interlocking signal. In particular, since the parent alarm device can transmit the interlock signal in preference to the child alarm device, the interlock signal from the parent alarm device can be received due to the arrangement, but the child alarm that detected the abnormality When there is a child alarm device (hidden terminal) that cannot receive the interlock signal from the device, the child alarm device (hidden terminal) can quickly receive the interlock signal and drive the notification means, Abnormalities can be reported quickly throughout the system.

  In addition, the control unit of the alarm device activates the reception function of the transmission / reception unit and performs carrier detection only during a predetermined carrier sense period before starting transmission of the radio signal from the transmission / reception unit. If no carrier is detected during the period, the radio signal is transmitted from the transceiver, and the carrier sense period is set to a predetermined time longer than the first pause period and the second pause period. Since the interlock signal from the alarm device that needs to transmit the interlock signal again is given priority over the interlock signal from the alarm device that needs to transmit the interlock signal for the first time, Information delay can be reduced while avoiding collisions.

  In addition, when the control unit of the parent alarm device receives the interlock signal transmitted from the child alarm device, after the transmission period of the interlock signal ends, the notification unit of all other child alarm devices is driven. In order to make it possible, the interlock transfer signal is transmitted to all the other child alarm devices, and the control unit of the child alarm device transmits the interlock transfer transmitted from the parent alarm device within the second pause period. When the signal is received, the interlocking signal is not transmitted from the transmission / reception unit, so that a signal collision can be avoided and an abnormality can be notified throughout the system.

1 is a configuration diagram of an alarm system according to Embodiment 1. FIG. 2 is a functional block diagram of a fire alarm device according to Embodiment 1. FIG. 3 is a timing chart illustrating a transmission operation of the fire alarm device according to the first embodiment. 3 is a timing chart illustrating a reception operation of the fire alarm device according to the first embodiment. It is a figure explaining the transmission / reception operation | movement of the interlocking signal when the main | base station which concerns on Embodiment 1 detects a fire. It is a figure explaining the transmission / reception operation | movement of the interlocking signal when the subunit | mobile_unit which concerns on Embodiment 1 detects a fire. It is a figure explaining the case where the subunit | mobile_unit which concerns on Embodiment 2 transmits the interlocking | linkage signal simultaneously. It is a figure explaining the transmission / reception operation | movement of the interlocking signal and interlocking transfer signal when the subunit | mobile_unit based on Embodiment 3 detects a fire.

Embodiment 1 FIG.
Hereinafter, in the first embodiment, a case where the present invention is applied to an alarm system including a fire alarm device that is driven by a battery and performs wireless communication will be described as an example.

[Configuration of alarm system and fire alarm]
FIG. 1 is a diagram showing a configuration of an alarm system 200 according to an embodiment of the present invention. The alarm system 200 includes a plurality of fire alarms 100. Each of these fire alarm devices 100 has a function of detecting a fire and a function of independently alarming.

  As will be described later, all of the fire alarm devices 100 are configured in the same manner, and can operate as a parent device or a child device by setting of an operation setting unit (not shown). In addition, in order to distinguish and explain each fire alarm device 100, the fire alarm device A, the fire alarm device B, the fire alarm device C, and the fire alarm device D may be referred to. In the first embodiment, the fire alarm device When A is a parent device (parent alarm device), fire alarm devices B to D are child devices (child alarm devices), and are called parent device A, child device B, child device C, child device D There is also. Here, the fire alarm A to the fire alarm D belong to one same group. Moreover, in FIG. 1, the continuous line which connects each fire alarm device 100 has shown that it can communicate mutually by radio | wireless communication. However, as for the arrangement of the fire alarm devices A to D, the parent device A is arranged in a region where the transmission ranges of the radio signals of all of the plurality of child devices B to D overlap, and the transmission / reception circuits 5 of the parent device A are plural. If it is the structure which contains all the subunit | mobile_units B-D in the transmission range of a radio signal, it will be realized as a system. In other words, the slave units B to D need only be arranged so as to communicate with the master unit A, and may not be arranged to communicate with all the slave units B to D.

  FIG. 2 is a functional block diagram showing the main configuration of the fire alarm 100 according to the embodiment of the present invention.

  In FIG. 2, the fire alarm 100 includes a control circuit 1, a battery 2, a power supply circuit 3, a battery voltage detection circuit 4, a transmission / reception circuit 5, an antenna 6, a fire detection circuit 7, an alarm sound control circuit 8, and an indicator lamp circuit 9. Prepare.

  The battery 2 supplies DC power to the power supply circuit 3. The power supply circuit 3 controls the voltage of the battery 2 to a predetermined voltage and supplies it to the control circuit 1, the transmission / reception circuit 5, the fire detection circuit 7, the alarm sound control circuit 8, and the indicator lamp circuit 9.

  The battery voltage detection circuit 4 detects the voltage of the battery 2 applied to the power supply circuit 3 and outputs a battery voltage detection signal corresponding to the detected voltage to the control circuit 1. The battery voltage detection circuit 4 outputs a signal to the control circuit 1 when detecting that the remaining battery level has decreased or the battery depletion threshold has been exceeded, and the alarm sound control circuit 8 and the indicator lamp circuit 9 are connected. The transmitter / receiver circuit 5 outputs a state signal including battery state information.

  The fire detection circuit 7 corresponds to a state detection unit of the present invention, detects a physical quantity or a physical change of a detection object such as smoke or heat based on a fire phenomenon, and outputs a signal corresponding to the detection content to the control circuit 1 To do. The alarm sound control circuit 8 corresponds to the notification means of the present invention, and is a circuit that controls the operation of sounding by a buzzer / speaker or the like. The indicator lamp circuit 9 corresponds to the notification means of the present invention, and is a circuit that controls the lighting operation of indicator lamps such as light emitting diodes.

  The transmission / reception circuit 5 is connected to an antenna 6 for transmitting / receiving a radio signal, and includes a transmission circuit 51 and a reception circuit 52. The reception circuit 52 is controlled by the control circuit 1 to perform intermittent reception operation at a predetermined cycle to detect a radio signal input from the antenna 6 and perform reception processing in the case of a signal addressed to itself. In the case of a signal other than that addressed to itself, no reception process is performed. The received signal is output to the control circuit 1. Further, the transmission circuit 51 is controlled by the control circuit 1 to perform transmission processing of a radio signal such as a status signal and an interlock signal described later.

  The control circuit 1 has a function of discriminating a fire state or the like based on a signal output from the fire detection circuit 7. In addition, when it is determined that the state is a fire state, the alarm sound control circuit 8 and the indicator lamp circuit 9 are controlled to issue an alarm (notification) by sound and an indicator lamp. Moreover, while performing a required process based on the signal which the transmission / reception circuit 5 received, the transmission / reception circuit 5 is controlled as needed and signals, such as a status signal, are transmitted to another fire alarm device.

  The storage element 11 is a nonvolatile memory such as an EEPROM (registered trademark), and stores programs executed by the control circuit 1 and various data. In addition, transmission periods Tx1, Tx2, Tx3, transmission suspension periods ST1, ST2, and intermittent reception interval Ts, carrier sense period C, inter-block suspension periods M1, M2, interlocking signal transmission period N1, interlocking transfer signal transmission period N2 to be described later The control circuit 1 controls the transmission / reception operation of the transmission / reception circuit 5 according to these data.

[Transmission / reception]
Next, the transmission operation and the reception operation of the fire alarm device 100 will be described. FIG. 3 is a timing chart showing the transmission operation of the fire alarm device 100 according to the first embodiment, and FIG. 4 is a timing chart showing the reception operation of the fire alarm device 100 according to the first embodiment.

(Transmission operation)
As shown in FIG. 3, when transmitting a signal such as a status signal or an interlocking signal, which will be described later, the control circuit 1 controls the transmission circuit 51 to transmit a signal during a transmission period and stop transmission of the signal. The pause period is alternately repeated. In the first embodiment, the transmission processing is performed so that the transmission time is 3 seconds or less and the transmission suspension time is 2 seconds or more in conformity with the standard RCR STD-30. As shown in FIG. 3, for example, three transmission periods and two transmission suspension periods are repeated in the order of transmission period Tx1, transmission suspension period ST1, transmission period Tx2, transmission suspension period ST2, and transmission period Tx3. In the first embodiment, these are collectively referred to as one transmission block, and this one block corresponds to the “predetermined transmission pattern” of the present invention. When a status signal or the like is transmitted by an interlocking signal transmission or regular transmission operation, the transmission operation is performed in units of one block. In the present embodiment, reception processing by the reception circuit 52 is not performed during the transmission periods Tx1, Tx2, and Tx3, and reception processing by the reception circuit 52 is not performed during the transmission suspension periods ST1 and ST2. For example, the transmission 1 block is set such that the transmission period Tx1 = 3 seconds, the transmission period Tx2 = 2.5 seconds, the transmission period Tx3 = 3 seconds, the transmission suspension period ST1 = 2 seconds, and the transmission suspension period ST2 = 2 seconds. In other words, transmission 1 block = 12.5 seconds, and therefore, an interlocking signal transmission period N1 and an interlocking transfer signal transmission period N2 described later, which are used to refer to the transmission 1 block, are also 12.5 seconds.

  The fire alarm device 100 performs carrier sense (carrier detection) for a predetermined time before transmitting various radio signals. The carrier sense period C is longer than the transmission suspension periods ST1 and ST2. For example, it is set to 4 seconds. By setting the carrier sense period C in this manner, when a carrier is detected by carrier sense, it is determined that another fire alarm device 100 is transmitting a signal with the transmission pattern shown in FIG. Can be avoided without transmitting the signal. Moreover, when a carrier is not detected by carrier sense, it can be judged that the other fire alarm device 100 is not transmitting a signal with the transmission pattern shown in FIG. 3, and a signal can be transmitted. The carrier sense period C only needs to be longer than the transmission suspension periods ST1 and ST2, and may be longer than 2 seconds in the present embodiment.

(Reception operation)
As shown in FIG. 4, the control circuit 1 activates the reception circuit 52 every intermittent reception interval Ts (for example, 7 seconds), and intermittent reception F1, F2, F3. . . I do. Then, it is checked whether or not a predetermined radio signal can be received. If the radio signal can be detected, reception processing is performed. If the wireless signal cannot be detected, the operation of the receiving circuit 52 is stopped. In this way, the current consumption of the receiving circuit 52 can be greatly reduced by starting the receiving circuit 52 at every intermittent reception interval Ts and leaving it in a stopped state in other cases. In the fire alarm 100, the intermittent reception interval Ts is 7 seconds, and the period from the start of the transmission suspension period ST1 to the end of the transmission suspension period ST2 in the transmission 1 block is 6.5 shorter than the intermittent reception interval Ts. Since the second is set, the radio signal transmitted from the other fire alarm 100 can be received in any one of the transmission periods Tx1, Tx2, and Tx3 in the transmission 1 block. However, the predetermined transmission pattern (relationship between the transmission period and the transmission suspension period) as the transmission operation and the intermittent reception interval Ts as the reception operation may not be limited to the above.

[Periodic sending operation]
In the alarm system 200 including the fire alarm 100 configured as described above, in order to check the status of each fire alarm 100, periodic transmission for status confirmation is performed during fire monitoring (steady state). Yes.

(Periodic transmission of parent device)
First, periodic transmission performed by the parent device A (fire alarm device A) for the child device will be described.

  The master unit A uses the group ID to which it belongs, a self-address for identifying the transmission source, and information including its own status as status signals for every slave unit B to D ( It transmits all at once to the fire alarms B to D).

  The subunit | mobile_unit BD performs the intermittent reception as mentioned above, and has received the signal addressed to self in this intermittent reception. In this intermittent reception, the slave units B to D determine that the radio wave abnormality has been confirmed when the next periodic transmission cannot be received within the predetermined time G2 since the previous periodic transmission from the master unit A was received. The sub-units B to D that have determined that the radio wave abnormality has been confirmed control the alarm sound control circuit 8 and the indicator lamp circuit 9 to notify the user that a radio wave abnormality has occurred by voice or indicator lamp. On the other hand, if the regular transmission from the parent device A can be received within the predetermined time G2, it is determined that the radio wave abnormality has not occurred and is normal. The predetermined time G2 is longer than the predetermined time G1, which is the periodic transmission cycle of the parent device A. For example, the predetermined time G2 can be approximately three times the predetermined time G1, and the predetermined time G1 = 48 hours. G2 = 144 hours.

(Regular transmission of slave unit)
Next, regular transmission performed by the slave units B to D with respect to the master unit A will be described.

  The slave units B to D transmit the group ID to which the slave unit belongs, the self address for identifying the transmission source, and information including the status of the slave unit B to the master unit A as a status signal. Note that the delay time randomly generated based on the addresses, serial numbers, etc. of the slave units B to D may be increased / decreased to a predetermined time G3 to shift the regular transmission timing of each slave unit B to D. By doing in this way, the probability that the interference by the subunit | mobile_unit BD simultaneously performing regular transmission can generate | occur | produce can be reduced.

  On the other hand, the parent device A performs intermittent reception as described above, and receives a signal addressed to itself in this intermittent reception. In this intermittent reception, if the next periodic transmission cannot be received within a predetermined time G4 since the previous periodic transmission from the subunits B to D was received in this intermittent reception, the parent unit A determines that the occurrence of radio wave abnormality has been confirmed. . The master A that has determined that the radio wave abnormality has been confirmed controls the alarm sound control circuit 8 and the indicator lamp circuit 9 to notify the user that a radio wave abnormality has occurred by means of voice or a display lamp. On the other hand, if the periodic transmission from the slave units B to D can be received within the predetermined time G4, it is determined that the radio wave abnormality has not occurred and is normal. The parent device A determines the presence or absence of radio wave abnormality for each of the child devices B to D registered in its own group. Further, the predetermined time G4 is a time longer than the predetermined time G3, which is the periodic transmission cycle of the slave units B to D, and can be, for example, about three times the predetermined time G3. The predetermined time G3 = 23 hours, The predetermined time G4 = 69 hours.

  Since the status signal transmitted in this periodic transmission includes the self-address of the fire alarm device 100 as the transmission source, which fire alarm device the fire alarm device 100 that received the periodic transmission receives from Can be distinguished. In addition, examples of the status information related to the parent device A and the child devices B to D transmitted in the regular transmission include the remaining battery level, the sensor state of the fire detection circuit 7 (deterioration, contamination, etc.), the number of reception processes (other than prescribed) The number of times of processing for radio). Further, examples of the status information regarding the group include the address and group ID of a slave unit in which an abnormality has occurred, the address and group ID of a slave unit in which wireless communication is not established, and the like.

  As described above, as a regular transmission operation (periodic monitoring operation), the parent device A performs periodic transmission to the child devices B to D every predetermined time G1, and the child devices B to D are transmitted from the parent device A. Whether or not a radio wave abnormality has occurred is determined based on whether or not the next periodic transmission has been received within a predetermined time G2 since the previous periodic transmission was received.

  Moreover, the subunit | mobile_unit BD performs regular transmission with respect to the main | base station A every predetermined time G3, and the main | base station A is the predetermined time G4 after receiving the regular transmission from each subunit | mobile_unit B-D last time. The presence / absence of radio wave abnormality is determined based on whether or not the next periodic transmission has been received.

  As described above, the regular monitoring operation is not limited to performing unidirectional communication between the parent device A and the child devices B to D, and may perform bidirectional communication. For example, the parent device A performs periodic transmission to the child devices B to D every predetermined time G5, and the child devices B to D receive the periodic transmission from the parent device A and The base unit A generates a radio wave abnormality depending on whether or not the next periodic response transmission has been received within a predetermined time G6 since the last time the periodic response transmission from the sub units B to D was received. On the other hand, the sub-units B to D determine whether or not a radio wave abnormality has occurred depending on whether or not the next periodic transmission has been received within a predetermined time G7 since the previous periodic transmission from the parent unit A was received. Judging. The predetermined times G6 and G7 are longer than the predetermined time G5, which is the regular transmission cycle of the parent device A, and can be, for example, about three times the predetermined time G5.

[Operation when a fire is detected]
Next, an outline of operation when a fire occurs in the monitoring area of the alarm system 200 during fire monitoring (steady state) will be described.

  First, the transmission / reception operation of the interlocking signal when the master unit detects a fire will be described with reference to FIG. When a fire occurs in the environment where the parent device A is installed, the parent device A detects the fire by the fire detection circuit 7, and controls the alarm sound control circuit 8 and the indicator light circuit 9 to fire alarm by sound or indicator light. To do.

  Next, during the carrier sense period C, the parent device A performs carrier sense before transmission (shown as “CS” in FIG. 5). If a carrier of a predetermined level or higher is not detected by this carrier sense, the interlock signal transmission process is started. Specifically, the transmission circuit 51 broadcasts information related to fire detection to the other fire alarm devices B to D (child devices B to D) as interlocking signals. At this time, the transmission of the interlocking signal is performed for one block, and then, for example, an inter-block pause period M1 of 2 seconds is set, and then the interlocking signal is transmitted again (retransmission) for one block. As described above, when the parent device A detects a fire, it transmits a total of two blocks of interlocking signals. When parent device A detects a fire, transmission of the interlocking transfer signal (transfer of the interlocking signal) is not performed. Therefore, when the master unit A transmits the interlocking signal for two blocks, the slave units B to D are interlocked. Increases the probability of receiving signals.

  On the other hand, the subunits B to D perform the intermittent reception operation at each intermittent reception interval Ts as described above. When the interlock signal is received by this intermittent reception operation, the alarm sound control circuit 8 and the indicator lamp circuit 9 are controlled to perform an interlock alarm by voice or indicator lamp.

  After that, when the master unit A no longer detects a fire, it self-recovers and stops the alarm, and transmits a recovery signal to the other slave units B to D. The restoration signal is transmitted for a total of two blocks in the same manner as the interlock signal. Then, the other slave units (fire alarm devices B to D) that have received the recovery signal also stop the alarm.

  Here, since the inter-block pause period M1 is set to be shorter than the carrier sense period C, the other fire alarms B to D can detect the fire by the carrier sense before the transmission, even if the fire is detected. Since the carrier of the interlocking signal transmitted from is detected, the interlocking signal or the like is not transmitted during the inter-block pause period M1, and the information delay can be reduced while avoiding a collision.

  Next, the transmission / reception operation of the interlocking signal when the slave detects a fire will be described with reference to FIG. Here, the case where the subunit | mobile_unit B detects a fire is demonstrated as an example. When a fire occurs in the environment where the child unit B is installed, the child unit B detects the fire by the fire detection circuit 7 and controls the alarm sound control circuit 8 and the indicator light circuit 9 to fire alarm by sound or indicator light. To do.

  Next, the slave unit B performs carrier sense before transmission (shown as “CS” in FIG. 6) during the carrier sense period C. If a carrier of a predetermined level or higher is not detected by this carrier sense, the interlock signal transmission process is started. Specifically, the transmission circuit 51 broadcasts information related to fire detection to other fire alarm devices A, C, D (master device A, slave devices C, D) as interlocking signals. At this time, the transmission of the interlocking signal is performed for one block, then the inter-block pause period M2 is set, and then the interlocking signal is transmitted for one block (retransmission) again. As described above, when the slave unit B detects a fire, it performs a total of two blocks of transmission of interlocking signals, thereby increasing the probability that the master unit A, the slave units C and D receive the interlocking signal. The inter-block pause period M2 is a predetermined time set individually for all the child devices B to D, for example, a predetermined time that is randomly generated based on the address, serial number, etc. of the child devices B to D. . The inter-block pause period M2 is longer than the inter-block pause period M1 and shorter than the carrier sense period C, and is set between 2 and 4 seconds, for example.

  On the other hand, the master unit A and the slave units C and D perform the intermittent reception operation at each intermittent reception interval Ts as described above. When the interlock signal is received by this intermittent reception operation, the alarm sound control circuit 8 and the indicator lamp circuit 9 are controlled to perform an interlock alarm by voice or indicator lamp.

  In addition, when the master unit A receives the interlock signal transmitted from the slave unit B, the master unit A transmits the interlock transfer signal to all the slave units B to D for the purpose of transferring the interlock signal after the transmission of the interlock signal. To do. The transmission of the interlocking transfer signal is performed subsequent to the transmission of the interlocking signal. Thereafter, when the slave unit B no longer detects a fire, it self-recovers and stops the alarm, and transmits a recovery signal to the other alarm units (master unit A, slave units C and D). When receiving the recovery signal, the master unit A transmits a recovery transfer signal to all the slave units B to D. The restoration signal and the restoration transfer signal are transmitted at the same timing as the transmission of the interlocking signal and the interlocking transfer signal. The other alarm devices (master device A, slave devices C, D) that have received the recovery signal and the recovery transfer signal also stop the alarm.

  Here, for example, as shown in FIG. 5 and FIG. 6, it is assumed that the parent device A and the child device B detect a fire and simultaneously transmit an interlocking signal. In this case, since the parent device A and the child device B collide with each other at the first transmission timing, the other alarm devices 100 cannot decode even when receiving the interlocking signal. However, after the transmission of the interlocking signal is completed and the first stop period M1, for example, 2 seconds elapses, the master alarm device A completes the transmission of the interlocking signal, and the child alarm device has a predetermined time. The second suspension period M2, for example, after 2 to 4 seconds have elapsed, the interlock signal is retransmitted. Here, the first suspension period M1 and the second suspension period M2 are transmitted to each alarm device 100, respectively. Since it is set individually, when transmitting the interlocking signal again, the retransmission timings of the master unit A and the slave unit B are different, and a part where each interlocking signal does not collide occurs. Can be received at the intermittent reception timing of the intermittent reception interval Ts, and the signal can be decoded. In particular, since the first suspension period M1 is set to a predetermined time shorter than the second suspension period M2, the parent device A capable of transmitting signals to all the child devices B to D is arranged due to the arrangement. The interlocking signal can be retransmitted in preference to the slaves B to D, and the probability that all alarm devices 100 can receive the interlocking signal early can be increased.

Embodiment 2. FIG.
Hereinafter, the second embodiment will be described. The difference from the first embodiment is that the control circuit 1 of each of the slave units B to D activates the reception function of the transmission / reception circuit 5 during the second pause period M2. If the carrier is detected and the carrier is detected during the second pause period M2, the interlock signal is not transmitted from the transmission / reception circuit 5, and the description of the same contents as in the first embodiment is omitted. .

  FIG. 7 is a diagram illustrating a case where a plurality of slave units simultaneously detect a fire and transmit an interlocking signal. In the example of FIG. 7, the slave unit B and the slave unit C detect the fire and transmit the interlock signal at the same time. In this case, the slave unit B and the slave unit C are simultaneously transmitted at the first transmission timing. Although the interlocking signal is transmitted, the other alarm devices (parent device A and child device D) cannot be accurately decoded even if the signals collide and are received.

  Here, the slave unit B and the slave unit C perform the carrier detection by starting the reception function of the transmission / reception circuit 5 during the inter-block pause period M2 after the transmission of the first block of the interlocking signal is completed. . Here, as described above, the inter-block pause period M2 is individually set for each of the slave units B to D. In the example of FIG. 7, the inter-block pause period M2 of the slave unit B is between the blocks of the slave unit C. It is shorter than the rest period M2. Therefore, when the interlock signal is transmitted again, the slave unit B having the short inter-block pause period M2 among the slave units B and C that have detected the abnormality is linked from the slave unit C having the long inter-block pause period M2. Since no signal is transmitted and no carrier is detected during the inter-block pause period M2, the interlock signal is transmitted. On the other hand, the slave unit C having a long inter-block pause period M2 is a slave unit having a short inter-block pause period M2. Since the interlock signal is transmitted from B and the carrier is detected by carrier detection during the inter-block pause period M2, the interlock signal is not transmitted, and therefore the interlock signal is transmitted only from one slave unit B. Does not happen. Therefore, the other alarm devices A and D (including the child device C) can reliably receive the interlocking signal. In addition, the subunit | mobile_unit C does not prevent a series of transmission of the interlocking signal and interlocking transfer signal by the said subunit | mobile_unit B by performing the carrier detection of the carrier sense period C before transmitting an interlocking signal again. Can be.

  Although not shown in FIG. 7, assuming that the master unit A and the slave units B and C simultaneously transmit interlocking signals, the master unit A and the slave units B and C detect an abnormality at the same time. When the interlocking signal is transmitted, the signals collide with each other at the first transmission timing. Therefore, the other alarm devices (child units D) cannot accurately decode the alarm signal even if the interlocking signal is received. Here, since the inter-block pause period M1 of the parent device A is set shorter than the inter-block pause period M2 of the slave units B and C, when transmitting the interlocking signal again, an alarm that has detected an abnormality is detected. Among the devices A, B, and C, the parent device A does not transmit the interlock signal from the slave devices B and C during the inter-block pause period M2, while the slave devices B and C Since the interlock signal is transmitted from the parent device A and the carrier is detected by carrier detection during the inter-block pause period M2, the interlock signal is transmitted only from the master device A because the interlock signal is not transmitted. There is no collision. Therefore, the other alarm devices B to D can receive the interlock signal from the parent device A. Thereby, the signal from the parent device A can be received due to the arrangement, but the child device D that cannot receive the interlocking signal from the child devices B and C that detect the abnormality (for example, the child device D is a hidden terminal). Is present, the slave unit D can receive the interlocking signal and drive the alarm sound control circuit 8 and the indicator lamp circuit 9, and can quickly notify the abnormality in the entire system.

Embodiment 3 FIG.
Hereinafter, the third embodiment will be described. The difference from the second embodiment is that when the control circuit 1 of the parent device A receives the interlock signal transmitted from the slave devices B to D, the transmission period of the interlock signal is increased. After the completion, in order to drive the alarm sound control circuit 8 and the indicator lamp circuit 9 of all the other slave units B to D, the interlocking transfer signal is transmitted to all the other slave units B to D, The control circuit 1 of the slave units B to D does not transmit the interlocking signal from the transmission / reception circuit 5 when the interlocking transfer signal transmitted from the master unit A is received within the inter-block pause period M2. Since this is the same as that of the second embodiment, description thereof is omitted.

  FIG. 8 is a diagram for explaining the transmission / reception operation of the interlocking signal and the interlocking transfer signal when the slave detects a fire. As described in the second embodiment, when the slave unit B finishes transmitting the first block of the interlocking signal, the control circuit 1 of the slave unit B activates the reception circuit 52 to stop the inter-block pause period. During M2, an attempt is made to receive an interlocking transfer signal or the like from the parent device A. At this time, if the interlock transfer signal is received from the parent device A, the transmission of the interlock signal is stopped. As a result, signal collision does not occur.

  Note that, when the master unit A receives the interlocking signal in the intermittent reception operation, the master unit A predicts the end of the interlocking signal transmission, and transmits the interlocking transfer signal after the interlocking signal transmission ends based on the prediction result. Can do. This will be briefly described below.

  For example, in the transmission process of one block, the transmission period Tx1 = 3 seconds, the transmission period Tx2 = 2.5 seconds, the transmission period Tx3 = 3 seconds, the transmission suspension period ST1 = 2 seconds, and the transmission suspension period ST2 = 2 seconds are set. , Tx1 and Tx3 each include 28 frames, and Tx2 includes 24 frames. In this case, a unique frame counter value indicated by numbers “80” to “1”, for example, is added to each transmission frame.

  Then, when receiving the interlock signal from the slave unit B in the intermittent reception process, the master unit A obtains the signal transmission start timing from the frame counter value included in the received interlock signal by a predetermined arithmetic expression. The signal transmission start timing is the length of the transfer standby period K shown in FIG. Here, the master unit A starts the transmission process of the interlocked transfer signal when the transfer standby period K has elapsed after receiving the interlocking signal from the slave unit B, that is, when the transfer start timing comes. Note that the transfer timing may be determined based on a transfer start timing table instead of obtaining the transfer start timing from a frame counter value included in the received interlocking signal by a predetermined arithmetic expression. In addition, when the interlock signal from the slave unit B is received in the intermittent reception process, the reception operation may be continued and it may be confirmed that the transmission of the interlock signal is completed.

  As described above, the alarm system used in the present embodiment includes the state detection unit 7 (fire detection circuit 7) that detects an abnormality in the installation environment, and the transmission / reception unit 5 (transmission / reception circuit 5) that transmits and receives radio signals. The state detection unit 7 controls the notification means 8 and 9 (alarm sound control circuit 8 and indicator lamp circuit 9) for notifying that an abnormality in the installation environment has been detected, and the transmission / reception unit 5 and the notification means 8 and 9 are controlled. A plurality of alarm devices 100 having a control unit 1 (control circuit 1), one of the plurality of alarm devices 100 being a parent alarm device A (parent device A), and the other alarm device 100 being a child alarm In the alarm system 200 that transmits and receives radio signals between the plurality of alarm devices 100 as the devices B to D (child devices B), the parent alarm device A includes all of the radio signals of the plurality of child alarm devices B to D. The parent alarm is placed in the area where the transmission range overlaps The transmission / reception unit 5 of A includes all the plurality of child alarm devices B to D within the transmission range of the radio signal, and when the state detection unit 7 detects an abnormality, the control unit 1 of the parent alarm device A In order to drive the notification means 8 and 9 of all the child alarm devices B to D, an interlocking signal for notifying the occurrence of abnormality is transmitted from the transmission / reception unit 5 to all the other child alarm devices B to D. After the transmission of the interlocking signal is completed and the first suspension period M1 (interblock suspension period M1) of a predetermined time has elapsed, the interlocking signal is transmitted from the transmitting / receiving unit 5 to all the other child alarm devices B˜. When the state detector 7 detects an abnormality, the control unit 1 of the child alarm devices B to D retransmits to D. In order to drive the notification means of all other alarm devices 100, An interlocking signal notifying the occurrence is sent from the transmitting / receiving unit 5 to all other alarm devices 100. After the transmission of the interlocking signal is completed and the second suspension period M2 (inter-block suspension period M2) of a predetermined time has elapsed, the interlocking signal is transmitted from the transmission / reception unit 5 to all other alarm devices 100. The first suspension period M1 is set to a predetermined time shorter than the second suspension period M2, and the second suspension period M2 is set for all the child alarm devices B to D. And a predetermined time set individually. When a plurality of alarm devices 100 detect an abnormality at the same time and transmit an interlocking signal, the signals collide with each other. Therefore, the other alarm devices 100 cannot decode even if they receive the interlocking signal. However, the parent alarm device A ends the transmission of the interlocking signal, and after the first pause period M1 of the predetermined time has elapsed, the child alarm devices B to D complete the transmission of the interlocking signal and the predetermined time After the second suspension period M2 elapses, the interlocking signal is retransmitted. Here, the first suspension period M1 and the second suspension period M2 are set individually for each alarm device 100. When the interlocking signal is transmitted again, the retransmit timing of each alarm device 100 is different, and a location where each interlocking signal does not collide occurs. Therefore, another alarm device 100 receives the signal at the location where the interlocking signal does not collide. Can decipher the signal. In particular, since the first suspension period M1 is set to a predetermined time shorter than the second suspension period M2, a parent alarm device capable of transmitting signals to all the child alarm devices B to D due to the arrangement. A can re-transmit the interlock signal in preference to the child alarm devices B to D, and the probability that all the alarm devices 100 can receive the interlock signal quickly can be increased.

  Further, the control unit 1 of the child alarm devices B to D activates the reception function of the transmission / reception unit 5 during the second pause period M2 to perform carrier detection, and during the second pause period M2 If a carrier is detected, the interlock signal is not transmitted from the transmission / reception unit 5, and therefore the interlock signal is transmitted from only one alarm device 100, so that no signal collision occurs. Therefore, the other alarm devices 100 can reliably receive the interlocking signal. In particular, since the parent alarm device A can transmit the interlocking signal in preference to the child alarm devices B to D, it is possible to receive the interlocking signal from the parent alarm device A because of the arrangement. When there is a child alarm device B to D (hidden terminal) that cannot receive the interlock signal from the child alarm device B to D that detects the alarm, the child alarm device B to D (hidden terminal) receives the interlock signal early. Thus, the notification means 8 and 9 can be driven, and as a result, the abnormality can be notified quickly in the entire system.

  In addition, the control unit 1 of the alarm device 100 activates the reception function of the transmission / reception unit 5 for carrier detection period C for a predetermined time before starting transmission of the radio signal from the transmission / reception unit 5 to perform carrier detection. If the carrier is not detected during the carrier sense period C, the wireless signal is transmitted from the transmission / reception unit 5, and the carrier sense period C includes the first pause period M1 and the second pause period. Since it is set to a predetermined time longer than M2, the interlock signal from the alarm device 100 that needs to transmit the interlock signal again is the interlock signal from the alarm device 100 that needs to transmit the interlock signal for the first time. Since the signal is transmitted with priority over the signal, the information delay can be reduced while avoiding the collision.

  Further, when the control unit 1 of the parent alarm device A receives the interlock signal transmitted from the child alarm devices B to D, after the transmission period of the interlock signal ends, all other child alarm devices In order to drive the notification means 8 and 9 of B to D, the interlocking transfer signal is transmitted to all the other child alarm devices B to D, and the control unit 1 of the child alarm devices B to D When the interlocking transfer signal transmitted from the parent alarm device A is received within the second pause period M2, the interlocking signal is not transmitted from the transmission / reception unit 5; Anomalies can be reported throughout the system.

  The interlock signal is a signal having a predetermined transmission pattern including a transmission period in which the signal is repeatedly transmitted, and the predetermined transmission pattern includes the transmission period and a transmission suspension period in which transmission of the interlock signal is suspended. Since this is repeatedly executed alternately, the other alarm devices 100 can receive the interlocking signal transmitted by the alarm device 100.

  Further, since the control unit 1 of the alarm devices B to D does not perform signal reception processing during the transmission suspension period, power consumption can be reduced.

  In the above embodiment, the interlocking signal is transmitted twice, but it may be two or more times.

  In the above description, the case where the present invention is applied to a fire alarm device that is driven by a battery and performs wireless communication has been described as an example, but the power supply method and communication method of the fire alarm device are not limited, In addition to fire alarms, it can also be applied to alarms for detecting abnormalities. Moreover, you may use for the receiver and detector of an automatic fire alarm system.

  DESCRIPTION OF SYMBOLS 1 Control circuit, 2 Battery, 3 Power supply circuit, 4 Battery voltage detection circuit, 5 Transmission / reception circuit, 6 Antenna, 7 Fire detection circuit, 8 Alarm sound control circuit, 9 Indicator light circuit, 11 Memory element, 51 Transmission circuit, 52 Reception Circuit, 100 fire alarm, 200 alarm system, C carrier sense period, K transfer waiting period, M1 inter-block pause period, M2 inter-block pause period, N1 interlock signal transmission period, N2 interlock transfer signal transmission period.

Claims (4)

A state detection unit that detects an abnormality in the installation environment, a transmission / reception unit that transmits / receives a radio signal, a notification unit that notifies that an abnormality in the installation environment is detected by the state detection unit, and the transmission / reception unit and the notification unit are controlled. A plurality of alarm devices having a control unit,
One of the plurality of alarm devices is a parent alarm device, the other alarm device is a child alarm device,
The parent alarm device is arranged in a region where the transmission ranges of radio signals of all the child alarm devices overlap,
The transmission / reception unit of the parent alarm device includes all of the plurality of child alarm devices within the transmission range of the radio signal,
When the state detection unit detects an abnormality, the control unit of the parent alarm device drives the notification means of all other child alarm devices, so the control unit of the child alarm device notifies all other alarm devices. In order to drive the means, the interlocking signal for notifying the occurrence of an abnormality is transmitted from the transmitting / receiving unit, and the interlocking signal is transmitted / received after the transmission of the interlocking signal is finished and a predetermined period of time has elapsed. In the alarm system for retransmitting from the unit and transmitting and receiving radio signals between the plurality of alarm devices,
The suspension period of the child alarm device is set as a second suspension period that is a different predetermined time set individually for all the child alarm devices, and the suspension period of the parent alarm device is the The first suspension period is set to a predetermined time shorter than the second suspension period,
When a plurality of the alarm devices simultaneously detect an abnormality and transmit an interlocking signal, the retransmission timing of each alarm device is made different, and the parent alarm device has priority over the child alarm device. An alarm system characterized in that the interlocking signal can be retransmitted. The control unit of the child alarm device activates the reception function of the transmission / reception unit during the second pause period to perform carrier detection, and if a carrier is detected during the second pause period, the interlocking The alarm system according to claim 1, wherein a signal is not transmitted from the transmission / reception unit. The control unit of the alarm device performs carrier detection by activating the reception function of the transmission / reception unit only during a predetermined carrier sense period before starting transmission of the radio signal from the transmission / reception unit. If no carrier is detected, the radio signal is transmitted from the transceiver unit,
The alarm system according to claim 1 or 2, wherein the carrier sense period is set to a predetermined time longer than the first suspension period and the second suspension period. When the interlock signal transmitted from the child alarm device is received, the control unit of the parent alarm device drives the notification means of all other child alarm devices after the transmission period of the interlock signal ends. , Send the linked transfer signal to all other child alarms,
The control unit of the child alarm device does not transmit the interlock signal from the transmitting / receiving unit when the interlock transfer signal transmitted from the parent alarm device is received within the second suspension period. The alarm system according to any one of claims 1 to 3.