JP2009026180A - Fire receiver and control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To automatically set and optimize a data holding time for each detector line depending on the installation environment of fire detectors only by receiver processing. <P>SOLUTION: A learning part 32 monitors non-fire events, for a detector line which are stored but not determined as fires, and sets a first holding level when determining a detector line not likely to cause non-fire events or sets a second holding level when determining a detector line likely to cause non-fire events. A first holding level reception part 34 operates in a first holding level state, and issues an alarm when receiving another event signal after one recovery operation in which the detector line is powered off temporarily and returned to the original monitored state a predetermined time after a detector event signal is output. A second holding level reception part 38 operates in a second holding level state, and issues an alarm when receiving another event signal after one or more recovery operations in which the detector line is powered off temporarily and returned to the original monitored state a predetermined time after the event signal is received. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention connects a plurality of fire detectors to a sensor line that also serves as a power supply line drawn out to a warning area, and receives an event signal of the sensor line when the fire detector detects a fire. The present invention relates to a fire receiver for alarming and a control method.

  Conventionally, in a fire alarm system known as a P-type system, a plurality of on / off type fire detectors are connected to a sensor line drawn from a receiver, and an event signal from the fire detector is sent to each line. Receives fire alarms.

  On the other hand, in a fire alarm system known as an R-type system, a terminal device such as a repeater or an analog fire detector having a transmission function is connected to a transmission line drawn from a receiver, and when a fire is detected. For example, based on a fire interrupt from the terminal device, issue a search command to identify the address of the terminal device that output the event, display the fire occurrence address, and collect and monitor fire data from the identified terminal device. ing.

  In such a conventional fire alarm system, it is most important to detect fire early and to give a warning to the building officials correctly. However, at present, depending on the installation environment of the fire detector, an event may be output even though no fire has occurred, and in some cases, a non-fire report may be reached.

  Conventionally, a storage reception function has been used as a receiver function for preventing false alarms caused by non-fire reports. The accumulation and reception function does not immediately alert even when an event signal is received, and if an event signal is obtained continuously after a predetermined accumulation time has elapsed, it is determined that a true fire has occurred and an alarm is issued.

  In the case of a P-type system fire receiver, when an event signal is received from the sensor line, the power supply to the sensor line is cut off after a certain period of time and then returned to the monitoring state. When the event is output once again after recovery, it is judged as a true fire and an alarm is given.

  Based on past statistical data, non-fire events that cause non-fire reports, which can cause non-fire reports, are more likely to occur depending on the installation environment of the fire detector, and are less likely to occur. It is known that the number of occurrences fluctuates.

Therefore, some R receivers and some fire detectors set the accumulation time individually according to the installation environment from the analog data of the temperature and smoke density detected by the fire detector. Discovery and reduction of non-fire and misinformation.
JP 2005-352919 A JP 2004-265148 A JP-A-9-288781

  However, in the conventional fire receiver of the P-type system, it is desirable to set and optimize the accumulation time for each sensor line in accordance with the environment of the warning area as in the case of the R-type receiver. Since analog data of temperature and smoke density cannot be obtained from the fire detector, there is a problem that it is difficult to individually set the accumulation time according to the installation environment.

The present invention automatically sets the accumulation time according to the installation environment of the fire detector for each sensor line only by the receiver processing without changing the configuration of the P-type fire alarm system or adding a sensor. The objective is to provide a fire receiver that can be optimized.

(Fire receiver)
The present invention relates to a fire receiver that connects a fire detector, monitors a sensor line drawn to a warning area, receives and accumulates event signals from the sensor line, and notifies a fire through a judgment process. ,
A non-fire event that has been accumulated but not determined to be fired is monitored to determine the non-fire event occurrence frequency, and a learning processing unit is provided to set a plurality of different accumulation levels according to the non-fire event occurrence frequency. Features.

  In addition, an accumulation level reception processing unit that temporarily recovers the event signal after the initial recovery start time has elapsed after receiving the event signal is provided, and the accumulation level reception processing unit stores the accumulation set by the learning processing unit. Different initial recovery start times depending on the level.

  The accumulation level reception processing unit temporarily changes the number of restorations according to the accumulation level set by the learning processing unit.

  Further, the accumulation level reception processing unit changes the preset accumulation level to another different accumulation level according to the non-fire event occurrence situation.

In another aspect of the present invention,
In a fire receiver that connects a fire sensor, monitors the sensor line drawn to the alert area, receives and accumulates event signals from the sensor line, and notifies the fire through a judgment process.
The non-fire event that received the event signal from the sensor line but did not reach the alarm by the storage function was monitored to determine the non-fire event occurrence frequency of the sensor line, and the sensor line was determined to be a low-occurrence sensor line. A learning processing unit that sets a first accumulation level and sets a second accumulation level when it is determined that the sensor line has a high occurrence frequency;
It operates in the setting state of the first accumulation level, and after the first predetermined time after receiving the first event signal, the sensor line in the event occurrence state is returned to the monitoring state once, and then once recovered, then again. A first accumulation level reception processing unit that determines that a fire has occurred when an event signal is received;
It operates in the setting state of the second accumulation level, and after the second predetermined time after receiving the first event signal, the sensor line in the event occurrence state is once returned to the monitoring state, and once recovered, once again. When receiving the event signal, the second accumulation level reception processing unit which performs the process of further recovering and monitoring again once or a plurality of times, and alarming when the event signal is received again after the last recovery,
It is provided with.

  Here, the second predetermined time of the second accumulation level reception processing unit is set to be shorter than the first predetermined time of the first accumulation level reception processing unit.

  The second accumulation level reception processing unit temporarily changes the number of restorations according to the elapsed time from the first restoration to the reception of the event signal again.

  The second accumulation level reception processing unit performs a change to reduce the preset number of times of restoration.

  The learning processing unit switches the setting from the preset accumulation level to another accumulation level when the non-fire event is determined after presetting either the first accumulation level or the second accumulation level, and after switching If a non-fire event is not determined for a predetermined period in the set accumulation level, the setting is switched to the accumulation level before switching.

  For example, after the initial setting of the first accumulation level, the learning processing unit switches to the setting of the second accumulation level when the non-fire event is determined, and the non-fire event is not determined for a predetermined period in the setting state of the second accumulation level. Switch to the setting of the first accumulation level. The second accumulation level may be initialized and switched to the first accumulation level.

  When the second accumulation level is set and the non-fire event is continuously detected a plurality of times within a predetermined period, the learning processing unit temporarily switches to the first accumulation level and then changes to the second accumulation level. return.

(Control method of fire receiver)
The present invention relates to a method of controlling a fire receiver that connects a fire sensor, monitors a sensor line drawn to a warning area, receives and accumulates event signals from the sensor line, and notifies a fire through a judgment process. In
When a non-fire event that has received an event signal from the sensor line but did not reach an alarm due to the accumulation function is monitored to determine the non-fire event occurrence frequency of the sensor line, and when it is determined that the sensor line has a low occurrence frequency A learning processing step of setting a first accumulation level and setting a second accumulation level when it is determined that the sensor line has a high occurrence frequency;
It operates in the setting state of the first accumulation level, and after the first predetermined time after receiving the first event signal, the sensor line in the event occurrence state is returned to the monitoring state once, and then once recovered, then again. A first accumulation level reception processing step of determining and alarming a fire when an event signal is received;
It operates in the setting state of the second accumulation level, and after the second predetermined time after receiving the first event signal, the sensor line in the event occurrence state is once returned to the monitoring state, and once recovered, once again. A second accumulation level reception processing step for performing a process of recovering and monitoring again once or more when an event signal is received, and warning when an event signal is received again after the last recovery;
It is provided with.

  According to the present invention, a non-fire event that has received an event signal but has not reached an alarm by the accumulation function is monitored, and if the non-fire event has not been long for a certain period of time, for example, one month, the first accumulation level is set. Is stored for a predetermined time and then restored once, and if an event signal is received again, an alarm is issued to automatically shorten the accumulation operation time and enable early detection of fire. .

  On the other hand, if a non-fire event occurs in a short period of time, for example within one month, the second accumulation level is set, and after the event signal is received and accumulated for a predetermined time, it is temporarily recovered, for example, three times. After receiving the event signal, an alarm is issued when the event signal is received again, so that the accumulation time is automatically extended to prevent false alarms against temporary increases in smoke concentration and temperature due to causes other than fire. Even in a type system, it is possible to set an appropriate accumulation time for each line according to the temperature and smoke density in the installation environment, and to detect fire early and reduce non-fire and false alarms.

  In addition, since the normal recovery is used as it is in the storage process of the P-type fire receiver and the storage time is changed by the number of times of recovery, the existing fire detector can be used as it is, and the circuit configuration of the fire receiver However, the existing receiving circuit unit having the recovery circuit unit can be used as it is, and can be realized easily and easily without the need for changing the circuit of the fire receiver and the fire detector.

Furthermore, the accumulation time can be set for each sensor line according to the installation environment, and the accumulation time can be finely optimized according to the installation environment.

  FIG. 1 is a block diagram showing an embodiment of a fire receiver having a storage reception function according to the present invention. In FIG. 1, sensor lines 12-1, 12-2,..., 12 -n are drawn out from the fire receiver 10 of the present embodiment toward a warning area. Is connected. As the fire sensor 14 connected to the sensor lines 12-1 to 12-n, various on-off type fire sensors such as a smoke sensor and a heat sensor can be connected.

  The fire receiver 10 is provided with an MPU 18. For the MPU 18, receiving circuit units 20-1 to 20-n and restoration circuit units 22-1 to 22-n are provided for each of the sensor lines 12-1 to 12-n. Is provided. For the MPU 18, an operation unit 24, an alarm display unit 26, a message output unit 28, and a memory 30 are provided.

  The MPU 18 includes a hardware environment of a computer, and this hardware environment connects a ROM, a RAM, a hard disk drive, and an interface for performing input / output to / from the outside to the CPU bus.

  Further, the MPU 18 is provided with a learning processing unit 32, a first accumulation level reception processing unit 34, and a second accumulation level reception processing unit 36 as functions of the present embodiment realized by execution of a program by a computer.

  Here, the basic fire receiving function of the fire receiver 10 of the present embodiment is that when the fire sensor 14 connected to the sensor lines 12-1 to 12-n detects a fire, the sensor line is connected to a low impedance. The event signal is output by causing the alarm current to flow by short-circuiting the signal to the MPU 18, and the receiver circuit units 20-1 to 20 -n detect the alarm current that flows in the own sensor line and receive the event signal. Output to.

  In addition, the fire receiver 10 of the present embodiment has a storage and reception function. For example, when an event signal is received by the receiving circuit unit 20-1, a predetermined time has elapsed after the event signal is received by the MPU 18 side. Later, the recovery circuit unit 22-1 is operated to temporarily shut off the power supply to the sensor line 12-1, and after the recovery, an alarm is issued when an event signal is received from the fire detector 14 again. It has a basic storage function. In the present embodiment, this basic accumulation function is treated as the first accumulation level reception process as will be clarified later.

  When the learning processing unit 32 provided in the MPU 18 receives the alarm signal from the sensor line, but monitors the non-fire event that did not result in an alarm by the accumulation function, and determines that the sensor line is unlikely to generate the non-fire alarm In addition, a first accumulation level is set for the sensor line. On the other hand, when it is determined that the non-fire event is likely to occur, a second accumulation level is set for the sensor line.

  The setting and switching of the first accumulation level and the second accumulation level, which are determined by determining the likelihood and non-occurrence of the non-fire event to be performed for each sensor line, will be further clarified in the later description.

  The first accumulation level reception processing unit 34 operates on the sensor line for which the first accumulation level is set by the learning processing unit 32, and recovers after a first predetermined time Tx1 after receiving the event signal from the sensor line. A temporary interruption of the power supply to the sensor line by the circuit unit to return to the original monitoring state is performed once, and then an alarm is issued when an event signal is received again. The processing operation of the first accumulation level reception processing unit 34 is the same as the basic accumulation reception performed by the fire receiver 10 having the conventional accumulation function.

  The second accumulation level reception processing unit 36 operates for the sensor line for which the second accumulation level is set by the learning processing unit 32, and after receiving the event signal from the sensor line, after the second predetermined time Tx2, Temporarily shuts off the power supply to the line and returns to the original monitoring state. Once the recovery is performed once (the same operation as the first accumulation level reception processing unit), it is temporarily recovered when the event signal is received again. The normal monitoring process is again performed one or more times, and an alarm is issued when an event signal is received again after the last recovery.

  For this reason, the number of restorations for accumulation reception in the first accumulation level reception processing unit 34 is one, whereas the number of restorations for accumulation reception in the second accumulation level reception processing unit 36 is, for example, three. Is set.

  FIG. 2 is a flowchart showing a schematic process of the fire reception process according to the present embodiment. In FIG. 2, in the fire reception process of this embodiment, in step S1, it is determined whether a non-fire event is likely to occur or a non-fire event is likely to occur for each sensor line by the learning process. The first accumulation level is set for a sensor line that is unlikely to occur, and the second accumulation level is set for a sensor line that is prone to non-fire events.

  Subsequently, in step S2, it is determined whether or not an event signal has been received for each sensor line. If an event signal is received, the process proceeds to step S3. If the first accumulation level is set by the learning process, the process proceeds to step S4. The process proceeds to the first accumulation level fire reception process. On the other hand, if the second accumulation level is set, the process proceeds to step S5 to execute the second accumulation level fire reception process.

  The learning process for determining the first accumulation level fire reception process or the second accumulation level fire reception process is automatically determined depending on whether or not a non-fire event is generated for each sensor line during operation. The first accumulation level or the second accumulation level, which is the content of the optimum accumulation reception that matches the installation environment, is automatically set.

  FIG. 3 is a time chart showing a learning process for setting the first accumulation level and the second accumulation level based on the non-fire event in the present embodiment. FIG. 3 (A) shows the setting of the first accumulation level and the second accumulation level, and FIG. 3 (B) shows the occurrence of non-fire events 38, 40, and 42 for the warning period on a weekly basis such as 0 to 4 weeks. Show.

  In the initial state in which the operation of the fire receiver is monitored, the first accumulation level is set assuming an environment in which a non-fire event is unlikely to occur for each sensor line regardless of the installation environment. If the non-fire event 38 occurs in the setting state of the first accumulation level, the setting is switched from the first accumulation level where the non-fire event is unlikely to occur to the second accumulation level where the non-fire event is likely to occur.

  After the second accumulation level is set, for example, it is monitored whether a non-fire event occurs for a certain period To, for example, T0 = 1 month, and the non-fire report is displayed for a certain period T0 = 1 month. If the non-fire event does not occur, the second accumulation level at which the non-fire event is likely to occur is switched to the first accumulation level at which the non-fire event is unlikely to occur.

  In a monitoring environment where a fire alarm system like this embodiment is installed, if non-fire events occur frequently based on past statistical data, the interval between occurrences of non-fire events is within 1 to 2 weeks. In some cases, it has been found that it may occur several times in a short time.

  Therefore, in this embodiment, the determination of switching from the first accumulation level at which a non-fire event is unlikely to occur to the second accumulation level at which a non-fire event is likely to occur is made immediately after the occurrence of the non-fire event. To the second accumulation level.

  On the other hand, switching from the second accumulation level, at which non-fire events are likely to occur, to the first accumulation level, at which non-fire events are less likely to occur, takes a month or so, and if there is no non-fire event, a non-fire event occurs. The first accumulation level, which is difficult to perform, is returned to.

  In FIG. 3B, after the non-fire event 40 occurs and the first accumulation level is switched to the second accumulation level, the non-fire event 42 occurs at a timing of less than one month after two weeks. ing. In this case, monitoring for a certain period To is reset and started every time the non-fire event 40 or 42 occurs.

  Therefore, the non-fire event 42 subsequent to the non-fire event 40 is reset and restarted for a certain period of time, and the second accumulation level to the first accumulation level in the fourth week after the non-fire event 42 has elapsed for a certain period To = 1 month. To switch to.

  The period without the non-fire event for returning from the second accumulation level to the first accumulation level is set to a certain period T0 = 1 month, but this is an example, and if necessary, the certain period T0 is less than one month, for example, 2 It may be a week or 3 weeks, or may be 5 weeks or 6 weeks of one month or more, and the fixed period T0 can be appropriately determined according to the situation of the monitoring environment in which the fire alarm system is set. . In this embodiment, the initial accumulation level is the second accumulation level, but this may be the first accumulation level.

  FIG. 4 is a flowchart showing details of the learning process in step S1 of FIG. In FIG. 4, when the non-fire event is determined in step S1, the learning process determines whether or not the first accumulation level is currently set in step S2. If the first accumulation level is set, the second accumulation is performed in step S3. Switch to the level setting and start monitoring for a certain period T0 = 1 month. If the second accumulation level is currently set in step S2, step S3 is skipped.

  If it is determined in step S1 that there is no non-fire event, it is determined in step S4 that one month has elapsed. Then, in step S5, if it is determined that the second accumulation level is currently set, the second accumulation level is set in step S6. Switch from setting to setting of first accumulation level.

  FIG. 5 is a time chart showing a first accumulation level fire reception process that operates when an event signal is received in a setting state of the first accumulation level set for an installation environment in which an event signal is unlikely to occur in the present embodiment. .

  FIG. 5A shows the sensor line voltage, and shows, for example, three levels of voltage of normal (monitoring) 24 volts, alarm (event output) 12 volts, and recovery about 0 volts. FIG. 5B shows an accumulation timer, which is activated when an alarm signal is first received. FIG. 5C shows an alarm output, FIG. 5D shows an accumulation time, and FIG. 5E shows an accumulation cancellation timer.

  In the first accumulation level fire reception process of the present embodiment, when the sensor transmits an event signal at time t1, the sensor line voltage decreases from the normal voltage to the alarm voltage (event output voltage). At time t2 after time T2 from the event output until the fire receiver starts up, the accumulation timer of FIG. 5B is activated and starts counting the first predetermined time Tx1. The first predetermined time Tx1 is set to Tx1 = about 6 seconds in the present embodiment.

  When the accumulation timer operates for Tx1 time, the power supply to the sensor line is temporarily cut off at time t3 to temporarily return to the original monitoring state for T3 time. By this restoration, the sensor line voltage drops from the alarm voltage (event output voltage) to the restoration voltage, and then returns to the normal voltage (monitoring voltage) again at time t4.

  By temporarily restoring the power supply to the sensor line, the power supply to the fire sensor of the sensor line that is outputting an event at this time is cut off, and the fire sensor is restored to the normal monitoring state. The time T3 from the time t3 to the time t4 in the temporary recovery is a recovery time. The recovery time T3 once means the line voltage disconnection time.

  When the normal voltage is restored after recovery at time t4, the fire detector connected to the sensor line is in the monitoring state again. At this time, when smoke inflow or heat exceeding the fire level is applied to the fire detector The fire detector again outputs an event at time t5, which is T1 hours after the recovery is completed once at time t3, and falls to the alarm voltage (event output voltage). The time T1 from time t4 to time t5 is the time from when the fire detector is temporarily recovered until the event is output again.

  When event output is performed again at time t5, the receiver outputs an alarm output as shown in FIG. 5C at time t6 after the time T2 from the event output of the sensor until the receiver starts up. become.

The time Ta from the time when the receiver is started up by the event signal at time t2 in the first accumulation level fire reception processing until the alarm output at time t6 is issued gives the accumulation time in the accumulation reception. This accumulation time Ta is Ta = Tx1 + T3 + T1 + T2.
Given in.

  Here, the time T1 is a time from when the fire detector is temporarily recovered until the alarm is issued again. Therefore, the time T1 is a time depending on the fire detector connected to the sensor line. In the case of a smoke sensor as a fire sensor used in this embodiment, T1 takes about T1 = 4 to 7 seconds. In the case of a heat sensor, T1 = about 3 seconds.

  For this reason, the accumulation time Ta in the first accumulation level fire reception process of this embodiment is about Ta = 12 seconds in the case of a smoke sensor, and about 10 seconds shorter than that in the case of a heat sensor.

  On the other hand, the accumulation cancellation timer of FIG. 5E sets Td = 50 seconds as the maximum time Td from the accumulation start at time t2 until the alarm is issued. For this reason, if the event signal cannot be obtained again by the time t7 when Td = 50 seconds set by the accumulation cancellation timer has elapsed after being restored at the time t3 to t4, the accumulation process is reset. To return to the normal monitoring state.

  In FIG. 5E, since the fire alarm is output at time t6, the accumulation cancellation timer is reset as indicated by the imaginary line at this time.

  FIG. 6 is a flowchart showing details of the first accumulation level fire reception process in step S3 of FIG. 2 and will be described below with reference to the time chart of FIG.

  In FIG. 6, in the first accumulation level fire reception process, when the event signal reception of the sensor line is determined in step S1, the accumulation timer of FIG. 5 (B) is started in step S2, and Tx1 time elapses in step S3. Judging.

  If it is determined that the time Tx1 has elapsed, the sensor line that was issued in step S4 is temporarily restored. Once a recurrence report is received in step S5 after recovery, fire alarm processing is performed in step S6.

  On the other hand, if no recurrence report is received in step S5, the elapse of the maximum accumulation time Td by the accumulation cancellation timer in FIG. 5E is determined in step S7. If no report has been received, accumulation termination processing is performed in step S10.

  The process when the accumulation ends in step S8 means the occurrence of a non-fire event that has received an event from the sensor line determined in the learning process in the present embodiment but has not reached an alarm by the accumulation function.

  FIG. 7 is a time chart showing the second accumulation level fire reception process in which the recovery is performed three times in the present embodiment. FIG. 7A shows the sensor line voltage, FIG. 7B shows the accumulation timer, and FIG. (C) shows an alarm output, FIG. 7 (D) shows an accumulation time, and FIG. 7 (E) shows an accumulation cancellation timer.

  In the second accumulation level fire reception process of FIG. 7, an event is output at time t1, the receiver starts up at time t2, operates the accumulation timer at the second predetermined time Tx, and then temporarily recovers at time t3. The process from the time when the sensor once recovers until the event is output again from time t4 to time t5 is the same as the first accumulation level fire reception process shown in FIG.

  The difference is that the accumulation timer time Tx2 is set to a short time. In the present embodiment, Tx1 in the first accumulation level fire reception process shown in FIG. 5 = about 6 seconds, whereas the accumulation timer time Tx2 in the second accumulation level fire reception process in FIG. = About 2.5 seconds, which is a little longer than about one third.

  In the second accumulation level fire reception process, after the first restoration, the restoration is performed twice more. FIG. 7 shows a state in which smoke or heat exceeding the fire level is applied to the fire detector. The first recovery is performed at time t3 to t4, and the sensor is temporarily recovered from the recovery at time t5 after the lapse of T1. The event is output again after the time T1 until the event is output, the receiver is started up from the detection of the sensor until the time t6, and after the time T4 until it is once again recovered, it is once the second time over the recovery time T3. Once restored.

  Subsequently, after the second time recovery, the sensor outputs the event again after a time T1 from the recovery to the event output again, and after the sensor outputs the event, the receiver starts up and then recovers again. After the time T4, the third recovery is performed once over the recovery time T3.

  When the event is output again at time t11 after a time T1 until the event is output again from the time when the fire detector is once restored after the third time is restored, which is the third time until the receiver starts up from the event output of the detector. At time t2 after elapse of time T2, the alarm is output as shown in FIG.

The accumulation time Tb of the second accumulation level fire reception process in a state where smoke or heat exceeding the fire level is applied to such a fire detector is the accumulation time Tb starting from the accumulation timer at time t2, and then at time t12. It is the time until the receiver outputs an alarm by the event output again after three times recovery.
Tb = Tx2 + (3 × T3) + (3 × T1) + (2 × T4) + T2
Given in.

  The shortest accumulation time Tb of the second accumulation level fire reception process is, for example, Tb> 20 seconds in the present embodiment when the fire sensor is a smoke sensor. Further, when the fire sensor is a heat sensor, the time T1 from when the sensor is temporarily restored to when an event is output again is shorter than the smoke sensor, so the accumulation time Tb ≦ 20 seconds.

  On the other hand, in FIG. 7 as well, the maximum accumulation time Td from the start of accumulation at time t2 is monitored by the accumulation cancellation timer in FIG. 7E, and fire alarm processing is finally performed until time t13 after three restorations. If it is not performed within the maximum accumulation time Td, the accumulation operation is canceled at time t13, and in this case, it is recognized as a non-fire event occurrence state not caused by a fire in the second accumulation level fire reception process. .

  In addition, the second accumulation level fire reception process in FIG. 7 is performed for a sensor line in an installation environment in which a non-fire event is likely to occur. In such a sensor line installation environment, a cause other than a fire is caused. When smoke concentration fluctuations and temperature fluctuations occur due to smoke, and even if a sensor event output that does not depend on fire is performed, smoke density and temperature exceeding the fire level are randomly generated without continuing Will end in the middle without being restored three times during the maximum accumulation time Td = 50 seconds by the accumulation cancellation timer, and will give a fire alarm in error for event output due to causes other than fire. Can be reliably prevented.

  FIG. 8 is a flowchart showing details of the second accumulation level fire reception process in step S4 of FIG. 2, and will be described below with reference to the time chart of FIG.

  In FIG. 8, in the second accumulation level fire reception process, when an event signal is generated in step S1, the number of restorations is once set to a threshold number Nth, for example, Nth = 3, in step S2. In S3, the accumulation timer of FIG. 7B is started, and when Tx2 time elapses are determined in Step S4, the event output line is temporarily restored, that is, firstly restored in Step S5. Subsequently, a counter N that once counts the number of times of restoration is counted up to N = N + 1.

  Subsequently, when it is determined in step S7 that the event has been output again, it is checked in step S8 whether the counter N has reached the threshold number Nth = 3. If not, the process returns to step S5 to perform the second recovery once. .

  Similarly, the recovery and the event output determination are repeated until the counter N reaches the threshold number Nth = 3 in step S8, and when N = 3, fire alarm processing is performed in step S9.

  On the other hand, if the event output is not determined again in step S7 after the recovery in step S5, the process proceeds to step S10, where it is determined whether the maximum accumulation time Td = 50 seconds has elapsed, and 50 seconds is set. If it has elapsed, the process proceeds to step S11, and the accumulation operation is terminated. This is given to the learning processing unit as a non-fire event occurrence state in the second accumulation level fire reception process.

  FIG. 9 is a time chart showing a process according to another embodiment in which the number of times of restoration is temporarily limited to two when the time until the event output is once again after it is restored in the second accumulation level fire reception process is too long. .

  Some of the fire detectors 14 connected to the sensor line from the fire receiver of FIG. 1 have a long time T1 until the event is output again after being restored once. In the second accumulation level fire reception process, Once the recovery is performed three times, the maximum storage time Td allowed for storage may not be within 50 seconds.

  Therefore, for fire detectors that do not output an event again within a predetermined period of time Tu, for example, Tu = about 10 seconds after the first restoration, fire detection takes a long time to output the event again. In this case, the number of times of restoration is once limited to two.

  As a result, even if a fire sensor that takes a long time to output an event again is connected to the sensor line, the second accumulation level fire reception process fires within the maximum accumulation time Td = 50 seconds that allow accumulation. Can be reliably alarmed.

  The process of limiting the recovery once in the second accumulation level fire reception process to two times will be described with reference to the time chart of FIG. 9A is a sensor line voltage, FIG. 9B is an accumulation timer, FIG. 9C is a newly provided recurrence report monitoring timer, FIG. 9D is an alarm output, and FIG. Is an accumulation time, and FIG. 9F is an accumulation cancellation timer.

  The sensor line event is output at time t1, the receiver starts up at time t2, the accumulation timer operates for Tx2 = about 2.5 seconds, and the recovery is performed once for the first recovery time T3 at time t3. Is called.

  However, once the restoration is made, the event output is not performed again even after the time t5 when the fire detector reaches the Tu time by the recurrence report monitoring timer activated at the time t2. Therefore, at the timing when the recurrence report monitoring timer at time t5 is timed up, this fire detector is determined to be a detector that takes a long time to output the event again, and the number of times of restoration is temporarily set on the receiver side. Change from 3 to 2 times.

  After that, the sensor outputs an event again at time t6, the second recovery is performed over time t3, and further event output is performed at time t9 after the elapse of T1, and the receiver starts up after time t2. The alarm output shown in FIG.

  As described above, once the number of restorations is limited to 3 to 2 for a fire detector with a long time until event output again, if the restoration is performed once three times, the maximum accumulation time Td by the accumulation timer is obtained. = Cannot issue a fire alarm for more than 50 seconds, but by limiting it to 2 times, the accumulation time Tb in FIG. 9 (E) is the time T1 from when the sensor is temporarily recovered until the event is output again. At most, it can be shortened by limiting it from 3 times to 2 times, and a fire alarm can be reliably issued with an accumulation time Tb that does not exceed the maximum accumulation time Td = 50 seconds.

  FIG. 10 is a flowchart showing a second accumulation level fire reception process according to the present embodiment, in which the process of once limiting the number of times of restoration of FIG. 9 is added. Steps S1 to S6 in FIG. 10 are the same as steps S1 to S6 in FIG. 8, and steps S9 to S15 in FIG. 10 are the same as steps S7 to S11 in FIG. The process of S8 is added.

That is, after the event output line is temporarily restored in step S5, the counter Tu is counted up in step S6, and the elapsed time Tu until the event output is monitored again in step S7, and steps S9, S14, S7 When Tu time elapses while waiting for event output again, in step S8, the threshold number N _{th of the} number of times of restoration is once set to N _th −1, and once another event is output by restoration, a fire alarm is issued. .

  FIG. 11 is a time chart showing a learning process for temporarily switching to the first accumulation level and then restoring it when the non-fire event continues twice in a short time in the setting state of the second accumulation level.

  In the present embodiment, the second accumulation level fire reception process according to the second accumulation level setting state temporarily performs the accumulation operation in the three-time restoration setting state, but the non-fire event that has not led to the fire has been continuously performed twice. As described above, if it is determined within a predetermined time T0, for example, T0 = 200 seconds, there is a possibility of a fire in the future.

  In order to cope with this, in the present embodiment, the first accumulation level corresponding to the environment in which the non-fire event is unlikely to occur is changed from the second accumulation level targeting the environment in which the current non-fire event is likely to occur. Temporarily switch to a state so that fires can be detected early. If the event signal is not received after the number of restorations is once switched to the first accumulation level, the original number of restorations is once again switched to the second accumulation level of three restorations.

  This process will be described with reference to the time chart of FIG. 11A shows the state of the first accumulation level and the second accumulation level, FIG. 11B is the accumulation operation, FIG. 11C is a non-fire event, and FIG. 11D is a monitoring timer. .

  The event signal 44 is received at the time t1 when the second accumulation level is set, and the first second accumulation level fire reception process 46, which is three times the number of restorations, is performed. Therefore, the accumulation is canceled at the time t2 after the maximum accumulation time Td = 50 seconds.

  Subsequently, assuming that the second event signal 48 is received at time t3, the second accumulation level fire reception processing 50 is performed in the same manner three times. However, in this case as well, the fire alarm is not reached. It is determined as a non-fire event, and the accumulation is canceled at time t4 after the maximum accumulation time Td = 50 seconds has elapsed.

  On the other hand, when the first event signal 44 is received at time t1, the monitoring timer shown in FIG. 11D is activated to monitor the elapse of a predetermined time Te = 200 seconds. Within this fixed time Te, the second accumulation level fire reception processing 46, 50 is performed twice in this case, so the current second accumulation level is set to the second accumulation level at time t4 when the accumulation is canceled at the second time. Switch to 1 accumulation level.

  After switching to the first accumulation level, the elapse of time Te = 200 seconds by the monitoring timer is waited, and if the accumulation process by the first accumulation level, that is, the first accumulation level fire reception process is not performed during that time, again at time t5 Return to the original second accumulation level setting.

  On the other hand, since the second consecutive accumulation level fire reception processes 46 and 50 are likely to cause a fire after that, when the first accumulation level is switched to the first accumulation level at time t4, the event output is further output at time t5. If there is, a fire alarm is issued in the accumulation operation by one recovery by the first accumulation level reception process, and a fire alarm is issued in a short time from the event output by switching to the first accumulation level. Can do.

  FIG. 12 is a flowchart showing details of the learning process shown in FIG. 11 for temporarily returning to the first accumulation level when the non-fire event by the second accumulation level fire reception process continues twice. Steps S1 to S6 in the learning process of FIG. 12 are the same as the learning process of FIG. 4, and steps S7 to S9 are newly added thereto.

  That is, if it is determined in step S1 that there is a non-fire event and then the setting of the second accumulation level is determined in step S2, whether or not a non-fire event has occurred twice within a predetermined time Te = 200 seconds in step S7. If it occurs twice, the first accumulation level is set in step S8.

  Subsequently, the process proceeds to step S9, and when T = 200 seconds have passed without a non-fire event, the process returns to step S3 to set the original second accumulation level.

  Note that the setting time Te of the monitoring timer in FIG. 11D requires (50 seconds × 2 times) = 100 seconds for the second non-fire event output of the second accumulation level, and then the first accumulation level. Because the maximum accumulation time of 50 seconds is required for fire monitoring by, the minimum is 150 seconds, but it is about 200 seconds including the free time when two non-fire events continue twice, but around 200 seconds In this range, an appropriate time may be set as necessary.

  FIG. 13 is a time chart showing a comparison of the receiver operation of the first accumulation level and the second accumulation level of the present embodiment. FIG. 13A shows the receiver operation at the first accumulation level, and FIG. 13B shows the receiver operation at the second accumulation level.

  The receiver operation at the first accumulation level is to hold the first received event signal, that is, the first signal, for Tx1 time determined by the accumulation timer after receiving the event signal, and then recover once and then start accumulation. The second signal reception time Ty, which is the reception of the event signal after the recovery, is set until the maximum storage time Te reaches 50 seconds.

  On the other hand, in the second accumulation level of FIG. 13B, the first signal is held by the first event signal reception for a short time which becomes the accumulation timer setting time Tx2 by the first event signal reception, and then 1 The second signal that is the second event signal associated with the first recovery and the third signal that is the event signal for the first recovery from the first recovery to the maximum accumulation time Td = 50 seconds. Furthermore, the reception time of the fourth signal, which is an event signal for the third recovery once, that is, the second to fourth signal reception time Ty2.

  FIG. 14 is a time chart comparing the receiver operations of the first accumulation level and the second accumulation level in the present embodiment when the smoke concentration temporarily changes beyond the fire level. FIG. 14A shows the smoke density, and the fire level is 10% / m. FIG. 14B shows the receiver operation at the first accumulation level, and FIG. 14C shows the receiver operation at the second accumulation level.

  When the smoke concentration exceeds the fire level at time t1, the fire detector outputs an event. For example, in the receiver operation at the first accumulation level in FIG. 14B, the receiver starts up at time t2 and reaches Tx1 time. The first recovery is performed after the first signal holding time. After the restoration, the smoke concentration exceeds the fire level for the time from when the sensor is restored once and the event is output again, so a fire alarm is issued at time t3.

  On the other hand, in the receiver operation at the second accumulation level in FIG. 14C, the receiver starts up at time t2 with respect to the event output of the sensor at time t1, and passes through the first signal holding time Tx2. After the first recovery, the smoke concentration has exceeded the fire level, so the receiver performs the second recovery after the sensor outputs an event again.

  After the second recovery, the smoke concentration is below the fire level after time t3, so the event output is not performed again. When the fire level is exceeded at time t4, the event output is performed again accordingly. This is the third recovery. After that, the smoke concentration does not exceed the fire level, and the accumulation is canceled after the second to fourth signal reception time Ty2 has elapsed, and in this case, no alarm output is performed.

  That is, in the present embodiment, the second accumulation in FIG. 14C is performed for an environment in which the smoke concentration changes due to a cause other than a fire that temporarily exceeds the fire level as shown in FIG. Because the receiver operation is set according to the level, the first accumulation level in FIG. 14 (B) for the smoke concentration change caused by causes other than fires may cause a fire alarm by mistake. It is possible to prevent false alarms reliably.

In addition, this invention is not limited to said embodiment, The appropriate deformation | transformation which does not impair the objective and advantage is included. The present invention is not limited by the numerical values shown in the above embodiments.

The block diagram which showed embodiment of the fire receiver provided with the accumulation | storage reception function by this invention The flowchart which showed the outline process of the fire reception process by this embodiment Time chart showing the learning process in the present embodiment for setting the first accumulation level and the second accumulation level based on the non-fire report The flowchart which showed the detail of the learning process in step S1 of FIG. The time chart which showed the 1st accumulation | storage level fire reception process which once recovers once in this embodiment The flowchart which showed the detail of the 1st accumulation | storage level fire reception process in step S3 of FIG. The time chart which showed the 2nd accumulation level fire reception processing which once recovers 3 times in this execution form The flowchart which showed the detail of the 2nd accumulation | storage level fire reception process in step S4 of FIG. Time chart showing the process of temporarily limiting the number of restoration to twice when the time until the event is output again after the restoration is too long in the second accumulation level fire reception process The flowchart which showed the 2nd accumulation | storage level reception process by this embodiment which added the process which once restrict | limits the frequency | count of restoration to 2 times by FIG. Time chart showing a learning process for temporarily setting the first accumulation level when two non-fire events continue in a short time during the setting of the second accumulation level The flowchart which showed the learning process in this embodiment which added the process of FIG. Time chart showing comparison between receiver operations of the first accumulation level and the second accumulation level of the present embodiment Time chart showing a comparison of the receiver operation of the first accumulation level and the second accumulation level in the present embodiment when the smoke concentration changes temporarily exceeding the fire level

Explanation of symbols

10: Fire receivers 12-1 to 12-n: Sensor line 14: Fire sensor 16: Terminator 18: MPU
20-1 to 20-n: reception circuit units 22-1 to 22-n: recovery circuit unit 24: operation unit 26: alarm display unit 28: message output unit 30: memory 32: learning processing unit 34: first storage Level reception processing unit 36: second accumulation level reception processing unit

Claims (16)

In a fire receiver that connects a fire sensor and monitors the sensor line drawn to the alert area, receives and accumulates event signals from the sensor line, and notifies the fire through a judgment process.
A non-fire event that has been accumulated but not determined to be a fire is monitored to determine a non-fire event occurrence frequency, and a learning processing unit that sets a plurality of different accumulation levels according to the non-fire event occurrence frequency is provided thing,
Features a fire receiver.
In the fire receiver according to claim 1,
An accumulation level reception processing unit for performing temporary recovery for temporarily recovering the event signal after the initial recovery start time has elapsed after receiving the event signal,
The accumulation level reception processing unit varies the initial recovery start time according to the accumulation level set by the learning processing unit,
Features a fire receiver.
In the fire receiver according to claim 1 or 2,
The accumulation level reception processing unit varies the number of times of restoration once according to the accumulation level set by the learning processing unit,
Features a fire receiver.
In the fire receiver according to claim 2 or 3,
The accumulation level reception processing unit changes the accumulation level set in advance to another different accumulation level according to the non-fire event occurrence situation,
Features a fire receiver.
In a fire receiver that connects a fire sensor and monitors the sensor line drawn to the alert area, receives and accumulates event signals from the sensor line, and notifies the fire through a judgment process.
The non-fire event occurrence frequency of the sensor line is determined by monitoring a non-fire event that has received an event signal from the sensor line but has not reached an alarm by a storage function, A learning processing unit that sets a first accumulation level when it is determined, and sets a second accumulation level when it is determined that the sensor line has a high occurrence frequency;
After operating in the setting state of the first accumulation level and returning the sensor line in the event occurrence state to the monitoring state once after a first predetermined time after receiving the first event signal, after once performing recovery A first accumulation level reception processing unit that determines that a fire has occurred when an event signal is received again;
After operating in the setting state of the second accumulation level and returning the sensor line in the event occurrence state to the monitoring state once after the second predetermined time after receiving the first event signal, after once performing recovery A second accumulation level reception processing unit that performs a process of once again recovering and monitoring again when the event signal is received again, and that warns when the event signal is received again after the last temporary recovery; and
A fire receiver characterized by comprising:
6. The fire receiver according to claim 5, wherein the second predetermined time of the second accumulation level reception processing unit is set to be shorter than the first predetermined time of the first accumulation level reception processing unit. Features a fire receiver.
6. The fire receiver according to claim 5, wherein the second accumulation level reception processing unit changes the number of times of restoration once according to the elapsed time from the first restoration to the reception of the event signal again. Features a fire receiver.
8. The fire receiver according to claim 7, wherein the second accumulation level reception processing unit makes a change to reduce a preset number of times of restoration.
6. The fire receiver according to claim 5, wherein the learning processing unit is preset when the non-fire event is determined after presetting either the first accumulation level or the second accumulation level. The fire is characterized in that the setting is switched from the accumulation level to another accumulation level, and when the non-fire event is not determined for a predetermined period in the accumulation level setting state after the switching, the fire is switched to the accumulation level setting before the switching. Receiving machine.
6. The fire receiver according to claim 5, wherein the learning processing unit temporarily sets the second accumulation level when a non-fire event is continuously determined a plurality of times within a predetermined period. A fire receiver characterized by switching to the setting of the first accumulation level and then returning to the second accumulation level.
In a control method of a fire receiver that connects a fire detector, monitors a sensor line drawn to a warning area, receives and accumulates event signals from the sensor line, and notifies a fire through a judgment process. ,
The non-fire event occurrence frequency of the sensor line is determined by monitoring a non-fire event that has received an event signal from the sensor line but has not reached an alarm by a storage function, A learning process step of setting a first accumulation level when discriminated, and setting a second accumulation level when discriminating the sensor line having a high occurrence frequency;
After operating in the setting state of the first accumulation level and returning the sensor line in the event occurrence state to the monitoring state once after a first predetermined time after receiving the first event signal, after once performing recovery A first accumulation level reception processing step for determining that a fire has occurred and alarming when an event signal is received again;
After operating in the setting state of the second accumulation level and returning the sensor line in the event occurrence state to the monitoring state once after the second predetermined time after receiving the first event signal, after once performing recovery A second accumulation level reception processing step for performing a process of once again recovering and monitoring again when an event signal is received again, and warning when an event signal is received again after the last temporary recovery;
A method of controlling a fire receiver, comprising:
12. The method of controlling a fire receiver according to claim 11, wherein the second predetermined time of the second accumulation level reception processing step is set shorter than the first predetermined time of the first accumulation level reception processing step. A method of controlling a fire receiver, characterized in that
12. The method of controlling a fire receiver according to claim 11, wherein the second accumulation level reception processing step sets the number of times of restoration once according to the elapsed time from the first restoration once until the event signal is received again. A control method for a fire receiver, characterized by being changed.
14. The fire receiver control method according to claim 13, wherein the second accumulation level reception processing step performs a change to reduce a preset number of times of restoration.
12. The method of controlling a fire receiver according to claim 11, wherein the learning processing step is performed in advance when the non-fire event is determined after setting either the first accumulation level or the second accumulation level in advance. The setting is switched from the set accumulation level to another accumulation level, and when the non-fire event is not determined for a predetermined period in the setting state of the accumulation level after the switching, the setting is switched to the setting of the accumulation level before the switching. Control method of fire receiver.
  12. The method of controlling a fire receiver according to claim 11, wherein the learning processing step is performed when a non-fire event is continuously determined a plurality of times within a predetermined period in the set state of the second accumulation level. A control method for a fire receiver, characterized in that after switching to the setting of the first accumulation level, the second accumulation level is restored.

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