JP7481834B2 - Fire alarm system - Google Patents

Description

The present invention relates to a fire alarm system that monitors fires by connecting terminals such as fire detectors and smoke control devices that have unique addresses set to a signal line drawn from a receiver.

Conventionally, in fire alarm systems known as R-type, a fire detector with a unique address and transmission function is connected to a signal line drawn from a receiver, along with an interlocking fire detector for interlocking control of fire shutters and other smoke control devices. In normal monitoring mode, the fire detectors are called in sequence with their detector addresses specified, and detection values such as smoke density and temperature are collected and monitored. In the event of a fire, a search command is issued from the receiver based on a fire interrupt signal from the fire detector to identify the address of the fire detector that triggered the alarm and to collect the detection values. If the detection value exceeds a specified fire alarm threshold, it is determined to be a fire and a fire alarm is output.

In the event of a fire, based on the fire interrupt signal from the linked fire detector, the address of the linked fire detector that triggered the alarm is identified and detection values such as smoke concentration and temperature are collected. If the detection value exceeds a specified linkage threshold, it is determined that there is a fire. Linkage control is then performed, with a control signal specifying the address of the linked device, for example a fire shutter, to close the shutter and form a fire compartment.

Here, the fire alarm threshold for determining whether a fire has occurred based on the detection value of the fire alarm fire detector is set to, for example, a threshold corresponding to a type 2 sensitivity, while the interlocking threshold for determining whether a fire has occurred based on the detection value of the interlocking fire detector and activating interlocking devices such as fire shutters is set to, for example, a low sensitivity threshold corresponding to a type 3 sensitivity.

The reason for this is that after a fire is detected with a fire warning equivalent to a Class 2 sensitivity level, allowing people to evacuate, the fire shutters are closed with a fire warning equivalent to a Class 3 sensitivity level, which has a lower sensitivity, to form a fire compartment.

The fire alarm threshold for Type 2 sensitivity set in the receiver can be changed within the Type 2 sensitivity range. For example, the sensitivity is changed according to a time schedule such that during daytime hours when people are present, the Type 2 sensitivity threshold is set to a higher value to achieve low sensitivity, and during nighttime hours when no one is present, the Type 2 sensitivity threshold is set to a lower value to achieve high sensitivity.

JP 2007-265353 A JP 2017-204807 A

However, with this type of fire alarm system, when a fire occurs, a fire alarm is issued based on a Class 2 sensitivity threshold for the smoke density from the fire alarm smoke detector, but a fire judgment is not made based on a Class 3 sensitivity threshold for the smoke density from the linked smoke detector, which creates the risk that the fire shutters will not operate.

For example, if a fire breaks out in a large open space with a wide ceiling, the smoke concentration entering a smoke detector installed on the ceiling surface may exceed the fire alarm threshold for Class 2 sensitivity, which is set at 10%/m, but may not exceed the fire alarm threshold for Class 3 sensitivity, which is set at 15%/m. In this case, the smoke concentration from the interlocking control smoke detector may not be enough to determine whether there is a fire, causing the fire shutter to not operate properly, and resulting in an insufficient fire compartment.

The present invention aims to provide a highly reliable fire alarm system that can perform linked control to reliably operate disaster prevention equipment such as fire shutters when a fire is confirmed, even if a fire is detected by setting a low sensitivity linked threshold to link and control disaster prevention equipment such as fire shutters, in contrast to the fire alarm threshold that detects and warns of a fire.

(Fire alarm system 1 )
The present invention relates to a fire alarm system in which a fire detector for fire alarm, a fire detector for interlocking, and a predetermined interlocking device are connected to a receiver.
On the receiver,
a fire alarm control unit that determines that there is a fire based on the detection value of the fire alarm fire detector and outputs a fire alarm, and also determines that there is a confirmed fire (a real fire) when a certain condition different from the determination of a fire is satisfied separately from the fire;
an interlocking control unit that determines a fire based on a detection value of the interlocking fire detector and controls the interlocking device;
a sensitivity change unit that changes the sensitivity in a direction that makes it easier to determine that a fire has occurred in the interlocking control unit when the fire alarm control unit determines that a fire has occurred (a real fire);
The present invention is characterized in that:

( Fire alarm system 2 )
The present invention comprises a receiver and
A fire alarm fire detector that outputs a signal to a receiver for use in determining whether a fire has occurred or not;
an interlocking fire detector that outputs a signal to the receiver, the signal being used for determining whether or not to interlock a predetermined interlocking device in the receiver, but not for determining whether or not to issue a fire alarm in the receiver;
In a fire alarm system equipped with
On the receiver,
a fire alarm control unit that detects a fire based on a detection value of the fire alarm fire detector and outputs a fire alarm, and also determines that a fire has been confirmed when a predetermined condition different from the fire detection condition is satisfied, separately from the fire;
an interlocking control unit that controls the interlocking device based on a detection value of the interlocking fire detector;
a sensitivity change unit that changes the sensitivity of the interlocking control unit in a direction that makes it easier to operate the interlocking device in the interlocking control unit when the fire alarm control unit determines that a fire has occurred;
The present invention is characterized in that:

(Fire confirmation)
The fire alarm control unit determines that a fire has been confirmed when, as specified conditions , it determines that a fire has occurred based on the detection values of at least two fire alarm fire detectors , when it receives a fire report signal from a transmitter connected to the signal line, or when it detects a fire determination operation of a fire determination switch provided in the receiver.

(Relay panel for distributed system)
One or more relay panels are connected to the receiver via a network line, and a fire alarm fire detector, an interlocking fire detector, and a predetermined interlocking device are connected to a signal line drawn from the relay panel,
On the relay board,
a fire alarm control unit that determines that a fire has occurred based on the detection value of the fire alarm fire detector and outputs a fire alarm from the receiver , and also determines that a fire has occurred when a predetermined condition different from the determination of a fire is satisfied separately from the fire ;
an interlocking control unit that determines a fire based on a detection value of the interlocking fire detector and controls the interlocking device;
a sensitivity change unit that changes the sensitivity in a direction that makes it easier to determine that a fire has occurred in the interlocking control unit when the fire alarm control unit determines that a fire has occurred;
The present invention is characterized in that:

(Basic Effects)
The present invention relates to a fire alarm system in which a fire alarm detector for fire alarm, an interlocking fire detector, and a predetermined interlocking device are connected to a receiver, and the receiver includes a fire alarm control unit which judges that there is a fire based on the detection value of the fire alarm detector for fire alarm, for example, when the detection value is equal to or exceeds a predetermined fire alarm threshold , and outputs a fire alarm, and judges that there is a confirmed fire (a real fire) when a predetermined condition different from the judgment of a fire is satisfied separately from the fire, an interlocking control unit which judges that there is a fire based on the detection value of the interlocking fire detector, for example, when the detection value is equal to or exceeds a predetermined interlocking threshold higher than the fire alarm threshold, and interlocks the interlocking device, and when the fire alarm control unit judges that there is a confirmed fire, and a sensitivity changing section which changes the sensitivity in a direction that makes it easier to determine that there is a fire.Therefore, when the fire alarm control section determines that there is a fire and there is no doubt that there is a fire, the pre-set interlocking threshold is changed to an interlocking threshold with a higher sensitivity, for example, the same threshold as the fire alarm threshold of the fire alarm control section which has determined that there is a fire at that time, thereby increasing the sensitivity.As a result, the detection value from the interlocking fire detector for a spreading fire is compared with the interlocking threshold which has been changed to the higher sensitivity, making it possible to reliably determine that there is a fire and operate smoke control equipment such as fire shutters through interlocking control, thereby making it possible to prevent the spread of the fire by forming a fire compartment, etc.

(Effect of changing the interlocking threshold to increase sensitivity)
In addition, when the fire alarm control unit determines that a fire has been confirmed, the sensitivity changing unit changes the interlocking threshold of the interlocking control unit to a lower interlocking threshold than the interlocking threshold at which a fire has been determined to be confirmed, thereby increasing the sensitivity.For example, the interlocking threshold of 15%/m for the smoke concentration, which is the initially set detection value of a smoke detector, is changed to a lower interlocking threshold, for example 10%/m, thereby increasing the sensitivity, so that a fire can be determined from the detection value of the interlocking smoke detector and disaster prevention equipment such as fire shutters can be operated reliably and quickly.

(Effect of changing the threshold from 3rd sensitivity to 2nd sensitivity)
In addition, a threshold equivalent to Class 2 sensitivity is preset in the fire alarm control unit as the fire alarm threshold, and a threshold equivalent to Class 3 sensitivity is preset in the interlocking control unit as the interlocking threshold, and the sensitivity change unit is configured so that when the fire alarm control unit determines that a fire has been confirmed, the threshold equivalent to Class 3 sensitivity set in the interlocking control unit is changed to the same threshold equivalent to Class 2 sensitivity set in the fire alarm control unit.Therefore, in the case of a smoke detector, the preset interlocking threshold for Class 3 sensitivity of 15%/m is changed to the interlocking threshold for Class 2 sensitivity of 10%/m, and in the case of a heat detector, the preset interlocking threshold for Class 3 sensitivity of 70°C is changed to the interlocking threshold for Class 2 sensitivity of 65°C. By changing the sensitivity from equivalent to Class 3 sensitivity to the higher equivalent to Class 2 sensitivity, a fire can be determined from the detection value of the interlocking fire detector and disaster prevention equipment such as fire shutters can be operated reliably and quickly.

(Effect of determining that a fire has occurred)
In addition, the fire alarm control unit is configured to determine that a fire has been confirmed when, as specified conditions , it detects a fire based on the detection values of at least two fire alarm fire detectors, receives a fire report signal from a transmitter connected to the signal line, or detects a fire confirmation operation of the fire confirmation switch provided on the receiver.Therefore , if it is determined that a fire has been confirmed, there is no doubt that there is a fire and there is no problem with false alarms, so that the sensitivity to the detection values from the linked fire detectors can be increased, and disaster prevention equipment such as fire shutters can be operated reliably and quickly.

(Effect of relay panel of distributed system)
In addition, one or more relay panels are connected to the receiver via a network line, and a fire alarm detector for fire alarm, an interlocking fire detector, and predetermined interlocking devices are connected to a signal line drawn from the relay panel, and the relay panel is provided with a fire alarm control section which judges a fire to be a fire based on a detection value of the fire alarm detector for fire alarm and causes the receiver to output a fire alarm, and judges a fire to be confirmed when a predetermined condition different from the judgment of a fire is satisfied separately from the fire , an interlocking control section which judges a fire to be a fire based on a detection value of the interlocking fire detector and interlocks the interlocking devices, and a sensitivity change section which changes the sensitivity in the interlocking control section to make it easier to judge a fire when the fire alarm control section judges a fire to be a fire. Therefore, even in a so-called distributed system in which one or more relay panels are connected to a receiver via a network line, when a fire is confirmed at the relay panel based on the detection value from a fire alarm fire detector connected to the signal line of the relay panel, the preset interlocking threshold is changed to a lower interlocking threshold to increase the sensitivity, and as a result, the detection value from the interlocking fire detector for a spreading fire is compared with the interlocking threshold which has been changed to a higher sensitivity, so that a fire is reliably determined to be a fire and smoke control equipment such as fire shutters connected to the signal line from the relay panel is reliably operated by interlocking control, making it possible to prevent the spread of the fire by forming a fire compartment, etc.

(Effect of changing the fire alarm threshold to increase sensitivity)
In addition, the sensitivity change unit, when the first fire is determined by the fire alarm control unit, changes the fire alarm threshold to a lower fire alarm threshold than the fire alarm threshold at which the fire was determined, to increase the sensitivity; for example, a threshold equivalent to a Class 2 sensitivity is preset in the fire alarm control unit as the fire threshold, and when the first fire is determined by the fire alarm control unit, the sensitivity change unit changes the threshold equivalent to Class 2 sensitivity to a threshold equivalent to Class 1 sensitivity, and when the fire alarm control unit determines the first fire from the detection value of the fire alarm fire detector and issues an alarm, the fire alarm threshold is changed, for example, from a threshold equivalent to Class 2 sensitivity to a threshold equivalent to Class 1 sensitivity to increase the sensitivity, thereby quickly determining whether a second or subsequent fire has spread. This allows the determination of fire to be made early, and the sensitivity of the interlocking threshold is quickly increased, allowing disaster prevention equipment such as fire shutters to be operated reliably and quickly against the spread of the fire.

FIG. 1 is an explanatory diagram showing an embodiment of a fire alarm system. A diagram showing the relationship between the sensitivity of smoke detectors and the smoke concentration threshold for determining a fire. A flowchart showing the control of collecting the detection values of the fire detector by the sub-CPU of FIG. A flowchart showing the fire alarm control, interlock control, and change of the interlock threshold by the main CPU A diagram showing the relationship between the sensitivity of heat detectors and the temperature threshold for determining a fire A diagram showing the fire alarm thresholds that are changed when the first fire is detected, along with the warning thresholds and linked thresholds. FIG. 1 is an explanatory diagram showing an embodiment of a fire alarm system that constitutes a distributed system in which a relay panel is connected to a receiver via a communication line.

[Fire alarm system]
(Outline of fire alarm system)
Fig. 1 is an explanatory diagram showing an embodiment of a fire alarm system. As shown in Fig. 1, a receiver 10 of, for example, an R type is installed in a monitoring center or a control room of a facility such as a large warehouse where a fire alarm system is installed, and signal lines 12-1 to 12-3 are drawn from the receiver 10 to the alert area in separate systems.

Multiple analog fire detectors 14-1 with transmission capabilities and unique addresses are connected to the signal line 12-1, and an on-off fire detector 18 and a transmitter 20 are connected to a detector line 17 drawn from a fire alarm repeater 16-1 with transmission capabilities and unique addresses.

Multiple interlocking analog fire detectors 14-2 with transmission capabilities and unique addresses are connected to the signal line 12-2, and an addressable transmitter 22 with transmission capabilities and unique addresses is also connected.

Furthermore, a fire shutter 24 is connected to the signal line 12-3 via an interlocking repeater 16-2 with a transmission function and a unique address set.

Here, the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 use, for example, analog smoke detectors, which detect the smoke density associated with a fire and output smoke density data as an analog detection value. In the following explanation, the smoke density data may be simply referred to as smoke density.

In addition, analog heat sensors may be used as the fire alarm analog fire sensor 14-1 and the interlocking analog fire sensor 14-2. The analog heat sensor detects the temperature associated with a fire and outputs the temperature data as an analog detection value.

The analog fire detector 14-1 for fire alarm is also set with a warning indication threshold (smoke concentration threshold) equivalent to, for example, Class 1 sensitivity, and transmits a fire interrupt signal when the detection value is equal to or exceeds the warning indication threshold. In the following explanation, the transmission of a fire interrupt signal by an analog detector may be referred to as a fire alarm.

The maximum number of addresses per line set for terminal devices such as the fire alarm analog fire detector 14-1, fire alarm repeater 16-1, interlocking analog fire detector 14-2, and interlocking repeater 16-2 connected to the signal lines 12-1 to 12-3 is, for example, 255, and a maximum of 255 terminal devices can be connected to each of the signal lines 12-1 to 12-3.

(Receiver functional configuration)
The receiver 10 is provided with a main CPU 26 and a plurality of sub-CPU boards 28-1 to 28-3, and the sub-CPU boards 28-1 to 28-3 are provided with sub-CPUs 30-1 to 30-3 and transmission sections 32-1 to 32-3.

The main CPU 26 and the sub-CPUs 30-1 to 30-3 are connected by a serial transfer bus 34 and send and receive data between them.

Connected to the main CPU 26 are a display 36 with a touch panel using a liquid crystal display panel or the like, a display unit 38 equipped with representative lights for fire, gas leaks, and faults, LED indicator lights, etc., an operation unit 40 equipped with various switches necessary for fire monitoring such as a fire assertion switch, an audio alarm unit 42 equipped with a speaker, and a reporting unit 44.

The main CPU 26 is provided with a fire alarm control unit 46, a linkage control unit 48, and a sensitivity change unit 50 as functions realized by executing a program.

The sub-CPUs 30-1 and 30-2 on the sub-CPU boards 28-1 and 28-2 control the collection of detection values from the fire alarm analog sensor 14-1 and the interlocking analog sensor 14-2, which are connected to the respective signal lines 12-1 and 12-2.

(Collection of detector detection data and fire alarm control)
The sub-CPU 30-1 of the sub-CPU board 28-1 instructs the transmission section 32-1 to transmit and receive signals to and from the analog fire detector 14-1 for fire alarm in accordance with a predetermined communication protocol, thereby controlling the collection of detection data.

The downstream signal from the transmission unit 32-1 to the analog fire detector 14-1 for fire alarm is transmitted in voltage mode. This voltage mode signal is transmitted as a voltage pulse that changes the line voltage of the signal line 12-1 between, for example, 18 volts and 30 volts.

In contrast, the upstream signal from the fire alarm analog fire detector 14-1 to the transmission unit 32-1 is transmitted in current mode. In this current mode, a signal current is passed through the signal line 12-1 at the timing of bit 1 of the transmission data, and the upstream signal is transmitted to the receiver 10 as a so-called current pulse train.

During normal monitoring, the data collection control by the sub-CPU 30-1 periodically instructs the transmission unit 32-1 to transmit a broadcast batch AD conversion signal including a batch AD conversion command. The analog fire detector 14-1 for fire alarm receives this batch AD conversion signal and converts the analog smoke density signal output from the smoke detection unit into a digital smoke density signal by AD conversion, and stores it as detection data. The sub-CPU 30-1 then transmits a call signal including a polling command that sequentially specifies the terminal addresses.

When the analog fire detector 14-1 receives a call signal with an address that matches its own address, it transmits a response signal including the smoke density data it is holding at that time to the transmission unit 32-1 of the receiver 10.

In addition, the analog fire detector 14-1 for fire alarms is set with a smoke density threshold equivalent to Class 1 sensitivity as a warning indication threshold, for example, a smoke density threshold of 5.0%/m, and when the detected smoke density data is equal to or exceeds the warning indication threshold, it is determined that a fire has been alerted and a fire interrupt signal is sent to the transmission unit 32-1 of the receiver 10.

When the sub-CPU 30-1 receives a fire interrupt signal via the transmission unit 32-1, it sends a group search command signal to identify the group that includes the analog fire detector 14-1 that has triggered the fire, then it sends an intra-group search command signal to identify the address of the analog fire detector 14-1 that has triggered the fire, collects smoke density data intensively, and transmits it to the main CPU 26 via the serial transfer bus 34.

The sub-CPU 30-1 collects smoke density intensively by shortening the transmission period of the batch AD conversion signal, and by transmitting a call signal specifying the address of the analog fire detector 14-1 that has issued a fire alarm after transmitting the batch AD conversion signal, so that only the smoke density data of the analog fire detector 14-1 is continuously collected.

The fire alarm control unit 46 of the main CPU 26 compares the smoke density data for fire alarms received from the sub-CPU 30-1 with a predetermined fire alarm threshold equivalent to Class 2 sensitivity, for example a fire alarm threshold of 10%/m, and determines that a fire has occurred if the smoke density is equal to or exceeds the fire alarm threshold, and performs fire alarm control.

The fire alarm control by the fire alarm control unit 46 involves turning on the fire indicator light on the display unit 38, outputting a predetermined main sound alarm indicating the occurrence of a fire from the speaker of the sound alarm unit 42, displaying fire alarm information including the location of the fire based on the address of the sensor where the fire was detected on the display 36, and further outputting a fire alarm signal to the outside by the alarm transmission unit 44 to perform predetermined alarm transmission control, etc.

(Collection of detector detection data and linked control)
The sub-CPU 30-2 of the sub-CPU board 28-2 instructs the transmission section 32-2 to transmit and receive signals to and from the linked analog fire detector 14-2 in accordance with a predetermined communication protocol, thereby controlling the collection of detection data.

The data collection control by the sub-CPU 30-2 is the same as that of the sub-CPU 30-1, and during normal monitoring, it instructs the transmission unit 32-2 at regular intervals to transmit a broadcast batch AD conversion signal including a batch AD conversion command, and the linked analog fire detector 14-2 that receives the batch AD conversion signal detects and retains the smoke density data as detection data. Next, the sub-CPU 30-2 transmits a call signal including a polling command that sequentially specifies the terminal addresses.

When the linked analog fire detector 14-2 receives a call signal with an address that matches its own address, it transmits a response signal including the smoke density data it is holding at that time to the transmission unit 32-2.

The interlocking analog fire detector 14-2 is set with a smoke density threshold of 5%/m equivalent to Class 1 sensitivity as the warning display threshold of the fire alarm analog detector 14-1, and when the detected smoke density is equal to or exceeds the warning display threshold, it determines that a fire has been alerted and transmits a fire interrupt signal to the transmission unit 32-2. Note that the warning display threshold of the interlocking analog fire detector 14-2 may be a smoke density threshold equivalent to Class 2 sensitivity, for example 10%/m, in addition to the smoke density threshold equivalent to Class 1 sensitivity.

When the sub-CPU 30-2 receives a fire interrupt signal via the transmission unit 32-2, it sends a group search command signal to identify the group that includes the linked analog fire detector 14-2 that triggered the fire, then sends an intra-group search command signal to identify the address of the linked analog fire detector 14-2 that triggered the fire, collects smoke density data in a centralized manner, and transmits it to the main CPU 26 via the serial transfer bus 34.

The interlocking control unit 48 of the main CPU 26 compares the smoke density for interlocking received from the sub-CPU 30-2 with a predetermined interlocking threshold value equivalent to the three types of sensitivity, for example an interlocking threshold value of 15%/m, and if the smoke density is equal to or exceeds the interlocking threshold value, it determines that a fire has occurred and performs interlocking control to close the fire shutter 24.

The interlocking control of the interlocking control unit 48 searches for the address of the interlocking repeater 16-2 to which the interlocking destination fire shutter 24 is connected from the interlocking information stored in advance in correspondence with the address of the interlocking analog fire detector 14-2 that detected a fire, and instructs the sub-CPU 30-3 to perform interlocking control specifying the interlocking destination address.

Sub-CPU 30-3, which receives an instruction for interlocking control from main CPU 26, instructs transmission unit 32-3 to transmit a shutter control signal specifying the interlocking destination address to signal line 12-3. The shutter control signal is received by interlocking repeater 16-2, which matches its own address, and fire shutter 24 is driven to close, forming a fire compartment.

(Sensitivity change control)
When the fire alarm control unit 46 determines that a fire has been confirmed, the sensitivity change unit 50 of the main CPU 26 controls the interlocking control unit 48 to change the interlocking threshold value in a direction that makes it easier to determine that a fire has occurred, for example, to an interlocking threshold value that is lower than the interlocking threshold value at which a fire has been confirmed, thereby increasing the sensitivity.

In this case, the interlocking control unit 48 is preset with an interlocking threshold of 15%/m, which is equivalent to a level 3 sensitivity, and therefore, when the fire alarm control unit 46 determines that a fire has been confirmed, the sensitivity change unit 50 performs control to change the interlocking threshold of 15%/m, which is equivalent to a level 3 sensitivity and which is set in the interlocking control unit 48, to, for example, an interlocking threshold of 10%/m, which is equivalent to a level 2 sensitivity and which is the same as that set in the fire alarm control unit 46.

The fire alarm control unit 46 may determine whether a fire has occurred in order to change the interlocking threshold of the interlocking control unit 48 via the sensitivity change unit 50 in the following cases.

(1) When a fire is determined based on the detection values of at least two analog fire detectors 14-1 that have triggered a fire alarm, i.e., when a first and second fire are determined to have occurred.

(2) When a fire communication signal is received from a transmitter 20 or an addressable transmitter 22 connected to the signal line, i.e., when a fire notification operation is performed manually.

(3) When a fire declaration operation of the fire declaration switch provided on the operation unit 40 of the receiver 10 is detected.

In addition, a fire may be determined to have occurred if the smoke density of the first analog fire detector 14-1 that has issued a fire alarm is sufficient to determine that a fire has occurred, for example, if it exceeds the upper threshold value equivalent to the third-class sensitivity.

When such a fire control unit 48 determines that a fire has occurred, it is definitely a fire, there is no problem with false alarms, and furthermore, since a fire alarm is also output, there is no reason to set the interlocking threshold for operating the fire shutters 24 to a lower sensitivity value than the fire alarm threshold for outputting a fire alarm and allowing evacuation. By changing the interlocking threshold to a value equal to or lower than the fire alarm threshold, the sensitivity for operating the fire shutters 24 is increased, and a fire is quickly and reliably determined from the smoke density detected by the interlocking analog fire detector 14-2, and interlocking control is performed to close the fire shutters 24, forming a fire compartment and preventing the spread of the fire.

(Analog smoke detector sensitivity and threshold)
2 is an explanatory diagram showing in a list the relationship between the sensitivity of a smoke detector and the smoke concentration threshold for determining a fire, in which FIG. 2(A) shows the threshold and threshold range corresponding to the sensitivity of the smoke detector, and FIG. 2(B) shows the smoke concentration thresholds for normal monitoring and confirmed fire monitoring for each threshold type when analog smoke detectors are used as the fire alarm analog fire detector 14-1 and the linked analog fire detector 14-2 in FIG. 1.

As shown in Figure 2 (A), in commonly used on-off type smoke detectors, a smoke density threshold of 5.0%/m is set as Class 1 sensitivity, and the smoke density threshold can be changed as needed within the range of 2.5%/m or more and less than 7.5%/m. A threshold value within this range is called a threshold value equivalent to Class 1 sensitivity.

In addition, the Type 2 sensitivity of on-off type smoke detectors is set with a smoke density threshold of 10.0%/m, and the smoke density threshold can be changed as needed within the range of 7.5%/m or more and less than 12.5%/m; a threshold value within this range is called the threshold value equivalent to Type 2 sensitivity.

Furthermore, the Type 3 sensitivity of on-off type smoke detectors is set with a smoke density threshold of 15.0%/m, and the smoke density threshold can be changed as necessary within the range of 12.5%/m or more and less than 17.5%/m; a threshold within this range is called the threshold equivalent to Type 3 sensitivity.

As shown in FIG. 2(B), the warning indication threshold for sending a fire interrupt signal set in the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 shown in FIG. 1 is set to, for example, a smoke density of 5.0%/m, which is equivalent to Class 1 sensitivity, for both normal monitoring and confirmed fire monitoring, and fires are detected with high sensitivity, Class 1 sensitivity.

The fire alarm threshold used for fire judgment by the fire alarm control unit 46 provided in the receiver 10 in FIG. 1 is set to, for example, a smoke density of 10.0%/m, which is equivalent to type 2 sensitivity, for both normal monitoring and confirmed fire monitoring.

Furthermore, the interlocking threshold value used for fire judgment by the interlocking control unit 48 provided in the receiver 10 in FIG. 1 is set to, for example, a smoke density of 15.0%/m, which is equivalent to a type 3 sensitivity, in normal monitoring, but in fire confirmation monitoring, the sensitivity change unit 50 changes it to a smoke density of 10.0%/m, which is equivalent to a type 2 sensitivity, which is higher than normal monitoring.

The smoke density of 10.0%/m equivalent to the second sensitivity, which is changed by the sensitivity change unit 50 when a confirmed fire is determined, is just one example, and it is sufficient to change the link threshold for normal monitoring to a lower high sensitivity link threshold, for example, any value within the threshold range of the second sensitivity shown in FIG. 2(A) of 7.5%/m or more and less than 12.5%/m. The link threshold to be changed is not limited to the threshold range of the second sensitivity, and may be changed to a smoke density equivalent to the third sensitivity of 12.5%/m or more and less than 15.0%/m, which is smaller than the smoke density of 15.0%/m equivalent to the third sensitivity of normal monitoring.

(Sub-CPU controlled).

Figure 3 is a flow chart showing the control of collecting detection values from analog fire detectors by the sub-CPU in Figure 1. Taking sub-CPU 30-1 as an example, the process is as follows.

As shown in FIG. 3, in step S1, the sub-CPU 30-1 performs call control of the terminal including the analog fire detector 14-1 for fire alarm connected to the signal line 12-1. As described above, this terminal call control transmits a batch AD conversion signal to cause the analog fire detector 14-1 for fire alarm to hold the smoke density data, and receives a response signal to the transmission of a call signal including a polling command that sequentially specifies the terminal addresses to obtain the smoke density data.

Next, in step S2, the sub-CPU 30-1 determines whether or not a fire interrupt signal transmitted in response to a fire alert has been received. If it determines that a fire interrupt signal has been received, it proceeds to step S3, where it searches for the address of the analog fire detector 14-1 that triggered the fire alert by transmitting an address search command signal, and in step S4 notifies the main CPU 26 of detector alert information indicating that the address and type of the alarm detector are for fire alerts.

Then, the sub-CPU 30-1 proceeds to step S5, shortens the transmission period of the batch AD conversion signal, and transmits a call signal specifying only the address of the alarm detector, thereby intensively collecting smoke density data from the analog fire detector 14-1 that has triggered a fire alarm, and notifying the main CPU 26.

Subsequently, the sub-CPU 30-1 repeats the process from step S1 until it determines in step S6 that the receiver 10 has been restored by operating the restoration switch, etc., and when it determines that a new fire interrupt signal, which is the second report, has been received, it searches for the address and intensively collects smoke density data, and collects the smoke density data corresponding to the first and second reports and transmits it to the main CPU 26.

When the sub-CPU 30-1 determines that recovery has occurred in step S6, it proceeds to step S7 to perform the specified recovery control, and then returns to normal monitoring using the terminal call control in step S1.

The sub-CPU 30-2 also performs the same control as shown in FIG. 3 on the interlocking analog fire detector 14-2 connected to the signal line 12-2.

(Main CPU control)
FIG. 4 is a flow chart showing the fire alarm control, interlock control, and change of the interlock threshold value by the main CPU.

As shown in FIG. 4, when the main CPU 26 determines in step S11 that it has received detector alarm information from sub-CPU 30-1 or sub-CPU 30-2, it proceeds to step S12, where it causes the display 36, display unit 38, and audio alarm unit 42 to display a warning indicating that the detector has triggered a fire alarm and output a predetermined warning alarm sound, thereby alerting the user of the increased risk of fire.

Next, if the main CPU 26 determines in step S13 that it has received a detection value from an alarm detector transmitted from sub-CPU 30-1 or sub-CPU 30-2, it proceeds to step S14. If it determines that the detector type is a fire alarm, it compares the fire alarm detection value with a fire alarm threshold, for example a fire alarm threshold of 10%/m, in step S15. If the fire alarm detection value is equal to or exceeds the fire alarm threshold, a fire is determined in step S16, and it proceeds to step S17 to output a fire alarm.

Then, the main CPU 30 proceeds to step S18, and if it determines that a fire has been confirmed by judging the second fire, receiving a fire notification signal from the transmitter, or detecting the operation of the fire confirmation switch, it proceeds to step S19 and changes the interlocking threshold value from 15%/m, which is equivalent to a type 3 sensitivity, to 10%/m, which is equivalent to a type 2 sensitivity, and changes the interlocking threshold value to a lower value to increase the sensitivity.

On the other hand, if the main CPU 26 determines in step S14 that the detector type is for interlocking, it proceeds to step S20, where it compares the interlocking detection value with the interlocking threshold value, and if it determines in step S21 that a fire has occurred because the interlocking detection value is equal to or exceeds the interlocking threshold value, it proceeds to step S22, where the fire shutter 24 is driven to close by interlocking control, forming a fire compartment.

Here, if the interlocking threshold value to be compared with the interlocking detection value in step S20 has been changed in step S18 from the previous interlocking threshold value of 15%/m equivalent to a type 3 sensitivity to a higher sensitivity interlocking threshold value of 10%/m equivalent to a type 2 sensitivity, the interlocking detection value in step S20 is compared with the changed interlocking threshold value of 10%/m equivalent to a type 2 sensitivity, and a fire is determined when the smoke concentration detected by the alarm detector is low, and when a fire is confirmed, the fire shutter 24 can be reliably driven to close due to the early fire determination.

The main CPU 26 repeats the process from step S13 until it determines in step S23 that recovery has been achieved by operating the recovery switch, and when recovery has been determined, it proceeds to step S24 to perform a predetermined recovery control, and then returns to the process from step S11.

[Embodiment using analog heat detector]
The fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 connected to the signal lines 12-1, 12-2 drawn from the receiver 10 in Figure 1 can also be analog heat detectors that detect temperature when exposed to a hot air current caused by a fire.

Figure 5 is an explanatory diagram showing the relationship between the sensitivity of a heat detector and the temperature threshold for determining a fire. Figure 5(A) shows the threshold and threshold range corresponding to the sensitivity of the heat detector, and Figure 5(B) shows the temperature thresholds for normal monitoring and fire confirmation monitoring for the threshold types when analog heat detectors are used as the fire alarm analog fire detector 14-1 and the linked analog fire detector 14-2 in Figure 1.

As shown in Figure 5 (A), in commonly used on-off type heat detectors, the first-class sensitivity is set to 55°C, and this can be changed to a range of 45°C or more and less than 60°C as necessary. A threshold value within this range is called a threshold value equivalent to the first-class sensitivity.

The second-class sensitivity of on-off type heat detectors is set to 65°C, but can be changed to a range between 60°C and 67.5°C as needed. A threshold value within this range is called the threshold value equivalent to the second-class sensitivity.

Furthermore, the third-level sensitivity of on-off type heat detectors is set to 70°C, but can be changed as necessary within the range of 67.5°C or higher and lower than 72.5°C, and the threshold value within this range is called the threshold value equivalent to the third-level sensitivity.

As shown in FIG. 5(B), the warning indication threshold for sending a fire interrupt signal set in the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 shown in FIG. 1 is set to, for example, a temperature threshold of 65°C, which is equivalent to Class 1 sensitivity, for both normal monitoring and confirmed fire monitoring, and fires are detected with high sensitivity, Class 1 sensitivity.

The fire alarm threshold used for fire judgment by the fire alarm control unit 46 provided in the receiver 10 in FIG. 1 is set to, for example, a temperature threshold of 65°C and equivalent to type 2 sensitivity for both normal monitoring and confirmed fire monitoring.

Furthermore, the interlocking threshold used for fire judgment by the interlocking control unit 48 provided in the receiver 10 in FIG. 1 is set to, for example, a temperature threshold of 70°C and equivalent to a type 3 sensitivity in normal monitoring, but in fire confirmation monitoring, the sensitivity change unit 50 changes it to a temperature threshold of 65°C, equivalent to a type 2 sensitivity that is higher than normal monitoring.

The temperature threshold of 55°C equivalent to the second sensitivity, which is changed by the sensitivity change unit 50 when a confirmed fire is determined, is just one example, and the normal monitoring interlocking threshold may be changed to a lower high sensitivity interlocking threshold, for example, any value within the threshold range of the second sensitivity shown in FIG. 5(A), 60.0°C or more and less than 67.5°C. In addition, the interlocking threshold to be changed is not limited to the threshold range of the second sensitivity, and includes changing to a smoke concentration equivalent to the third sensitivity, 67.5°C or more and less than 70°C, which is lower than the temperature threshold of 70°C equivalent to the third sensitivity of normal monitoring.

In this way, even when analog heat detectors are used as the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 in FIG. 1, if a fire is confirmed and there is no doubt that it is a fire, the preset interlocking temperature threshold equivalent to Class 3 sensitivity is changed to a higher sensitivity temperature threshold equivalent to Class 2 sensitivity, for example, the same threshold as the Class 2 sensitivity temperature threshold used to determine whether or not there is a fire at that time, thereby increasing the sensitivity. As a result, the detection value from the interlocking analog fire detector 14-2 due to a spreading fire is compared with the temperature threshold changed to the higher sensitivity, and it is reliably determined to be a fire, and the fire shutter 24 is operated by interlocking control, making it possible to prevent the spread of the fire by forming a fire compartment.

[Embodiment for changing fire alarm threshold ]
The sensitivity change unit 50 provided in the main CPU 26 of the receiver 10 shown in Figure 1 changes the interlocking threshold of the interlocking control unit 48 to a lower interlocking threshold to increase the sensitivity when the fire alarm control unit 46 determines that a fire has been confirmed.However, in another embodiment, the sensitivity change unit 50 may be configured to control the fire alarm threshold of the fire alarm control unit 46 to a lower fire alarm threshold to increase the sensitivity when the fire alarm control unit 46 determines that a first fire has been reported.

Figure 6 is an explanatory diagram showing a list of the fire alarm thresholds that are changed when a first fire is detected, along with the warning display thresholds and interlocking thresholds. Figure 6 (A) shows the case of an analog smoke detector, and Figure 6 (B) shows the case of an analog heat detector.

When analog smoke detectors are used as the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 in FIG. 1, the fire alarm control unit 46 of the receiver 10 is set to a smoke density threshold of 10.0%/m, which is equivalent to Class 2 sensitivity, as the fire alarm threshold during normal monitoring, as shown in FIG. 6 (A).

When the fire alarm control unit 46 determines that a first fire has occurred, the sensitivity change unit 50 increases the sensitivity by changing the smoke density threshold value of 10%/m, which is equivalent to Class 2 sensitivity and has been set as the fire alarm threshold value up until that point, to, for example, a smoke density threshold value of 7.5%/m, which is equivalent to Class 1 sensitivity.

On the other hand, when analog heat detectors are used as the fire alarm analog fire detector 14-1 and the interlocking analog fire detector 14-2 in FIG. 1, the fire alarm control unit 46 of the receiver 10 is set to a temperature threshold of 65°C, which is equivalent to the second-class sensitivity, as the fire alarm threshold during normal monitoring, as shown in FIG. 6 (B).

When the fire alarm control unit 46 determines that a first fire has occurred, the sensitivity change unit 50 changes the temperature threshold value of 65°C, which is equivalent to Class 2 sensitivity and which has been set as the fire alarm threshold value, to, for example, a temperature threshold value of 57.5°C, which is equivalent to Class 1 sensitivity, thereby increasing the sensitivity.

In this way, when the fire alarm control unit 46 judges that there is a fire on the first report, the sensitivity change unit 50, for example, changes the fire alarm threshold value equivalent to Class 2 sensitivity to a fire alarm threshold value equivalent to Class 1 sensitivity to increase the sensitivity, thereby enabling the system to quickly judge that there is a fire on the second report and thereafter in response to the spread of the fire.

When the fire alarm control unit 46 makes a quicker decision to determine whether or not there is a fire based on the second report, the sensitivity change unit 50 can quickly change the sensitivity of the interlocking threshold to increase, and the fire shutter can be driven to close reliably and quickly to prevent the fire from spreading.

[Embodiment of a distributed system composed of a receiver and a relay panel]
FIG. 7 is an explanatory diagram showing an embodiment of a fire alarm system constituting a distributed system in which a relay panel is connected to a receiver via a network line.

When the facility to be monitored is large, such as being divided into multiple warehouses, as shown in FIG. 7, in addition to the receiver 10 installed in a disaster prevention center, etc., a relay panel 100 is installed, for example, for each warehouse, and the receiver 10 and the relay panel 100 are connected for communication by a network line 104 such as Ethernet (registered trademark).

The receiver 10 is the same as that shown in FIG. 1, whereas the relay panel 100 is configured with the exception of the receiver 10 in FIG. 1, excluding the operation and display functions including the display 36, display unit 38, operation unit 40, and audio alarm unit 42, and is otherwise basically the same as the receiver 10, and further includes the functions of a fire alarm control unit 146, an interlocking control unit 148, and a sensitivity change unit 150.

Signal lines 102-1 to 102-3 are drawn from the relay panel 100, with the fire alarm analog fire detector 14-1 connected to signal line 102-1, the interlocking analog fire detector 14-2 connected to signal line 102-2, and the fire shutter 24 connected to signal line 102-3 via the interlocking repeater 16-2.

The fire alarm control unit 146 of the relay panel 100 determines that there is a fire when the detection value of the fire alarm analog fire detector 14-1 is equal to or exceeds a predetermined fire alarm threshold value equivalent to, for example, Class 2 sensitivity, and instructs the receiver 10 to output a fire alarm.

The interlocking control unit 148 of the relay panel 100 determines that there is a fire when the detection value of the interlocking analog fire detector 14-2 is higher than the fire alarm threshold, for example, equal to or exceeds a predetermined interlocking threshold equivalent to a level 3 sensitivity, and drives the fire shutter 24 to close and form a fire compartment by sending a control signal specifying the address of the interlocking repeater 16-2 in the interlocking relationship.

In addition, when the fire monitoring control unit 146 determines that a fire has occurred, the sensitivity change unit 150 of the relay panel 100 changes the interlocking threshold value equivalent to the third sensitivity level set in the interlocking control unit 148 to a predetermined interlocking threshold value equivalent to the second sensitivity level, thereby increasing the sensitivity.

Even in this distributed system in which the relay panel 100 is connected to the receiver 10 via the network line 104, if the relay panel 100 determines that there is a fire based on the detection value from the fire alarm analog fire detector 14-1 connected to the signal line 102-1 from the relay panel 100, the preset interlocking threshold is changed to a lower interlocking threshold to increase the sensitivity. As a result, the detection value from the interlocking analog fire detector 14-2 for a spreading fire is compared with the interlocking threshold changed to a higher sensitivity, and a fire is reliably determined to be a fire, and the fire shutter 24 connected to the signal line 102-3 from the relay panel 100 via the interlocking repeater 16-2 is reliably operated by interlocking control, making it possible to prevent the spread of the fire by forming a fire compartment, etc.

The analog heat detector embodiment shown in FIG. 5 and the embodiment for changing the fire alarm threshold shown in FIG. 6 can be applied to the relay panel 100 in the same manner as in the case of the receiver.

[Modifications of the present invention]
(Terminal Equipment)
In the above embodiment, a fire shutter is taken as an example of a terminal device to be interlocked and controlled, but interlocking control of other suitable disaster prevention devices such as a fire door, a smoke exhaust damper, etc. is also included.

(others)
Furthermore, the present invention includes appropriate modifications that do not impair the objects and advantages of the present invention, and is not limited to the numerical values shown in the above embodiment.

10: Receiver 12-1 to 12-3, 102-1 to 102-3: Signal line 14-1: Analog fire detector for fire alarm 14-2: Analog fire detector for interlocking 16-1: Fire alarm repeater 16-2: Interlocking repeater 17: Detector line 18: On/off fire detector 20: Transmitter 22: Addressable transmitter 24: Fire shutter 26: Main CPU
28-1 to 28-3: Sub CPU boards 30-1 to 30-3: Sub CPU
32-1 to 32-3: Transmission unit 34: Serial transfer bus 36: Display 38: Display unit 40: Operation unit 42: Acoustic alarm unit 44: Notification unit 46, 146: Fire alarm control unit 48, 148: Interlocking control unit 50, 150: Sensitivity change unit 100: Relay panel 104: Network line

Claims (4)

In a fire alarm system in which a fire detector for fire alarm, a fire detector for interlocking, and a specified interlocking device are connected to a receiver,
The receiver includes:
a fire alarm control unit that determines a fire based on the detection value of the fire alarm fire detector and outputs a fire alarm, and determines a fire to be confirmed when a predetermined condition different from the determination of the fire is satisfied separately from the fire ;
an interlocking control unit that determines a fire based on a detection value of the interlocking fire detector and controls the interlocking device;
a sensitivity change unit that changes the sensitivity in the interlocking control unit in a direction that makes it easier to determine that a fire has occurred when the fire alarm control unit determines that a fire has occurred;
A fire alarm system comprising:
In the fire alarm system according to claim 1 ,
The fire alarm control unit determines that a fire has been confirmed when , as the specified condition , a fire is determined based on the detection values of at least two of the fire detectors for fire alarm, a fire report signal is received from a transmitter connected to a signal line, or a fire determination operation of a fire determination switch provided on the receiver is detected.
In the fire alarm system according to claim 1,
One or more relay boards are connected to the receiver via a network line, and a fire alarm fire detector, an interlocking fire detector, and a predetermined interlocking device are connected to a signal line drawn from the relay board,
The relay board,
a fire alarm control unit that determines a fire based on the detection value of the fire alarm fire detector and outputs a fire alarm from the receiver, and determines that a fire has been confirmed when a predetermined condition different from the determination of a fire is satisfied separately from the fire ;
an interlocking control unit that determines a fire based on a detection value of the interlocking fire detector and controls the interlocking device;
a sensitivity change unit that changes the sensitivity in the interlocking control unit in a direction that makes it easier to determine that a fire has occurred when the fire alarm control unit determines that a fire has occurred;
A fire alarm system comprising:
A receiver;
a fire alarm fire detector that outputs a signal to the receiver for use in determining whether a fire has occurred or not;
a fire detector for interlocking that outputs a signal to the receiver, the signal being used for determining whether or not to interlock a predetermined device for interlocking in the receiver, but not for determining whether or not to issue a fire alarm in the receiver;
In a fire alarm system equipped with
The receiver includes:
A fire alarm control unit that determines a fire based on the detection value of the fire alarm fire detector and outputs a fire alarm, and determines that a fire has been confirmed when a predetermined condition different from the determination of the fire is satisfied separately from the fire;
An interlocking control unit that controls the interlocking device based on the detection value of the interlocking fire detector;
a sensitivity change unit that changes the sensitivity of the interlocking control unit in a direction that makes it easier to interlock the interlocking device when the fire alarm control unit determines that a fire has been confirmed;
A fire alarm system comprising:

Images