JP7538588B2 - Fire alarm system - Google Patents

Description

The present invention relates to a fire alarm system, and in particular to a fire alarm system suitable for detecting fires in buildings that are normally unoccupied.

Failures at cultural properties in recent years have raised interest in disaster prevention measures for cultural properties. In particular, there is a strong demand for fire alarm systems that are suitable for detecting fires in buildings that are usually unoccupied.

Taking cultural properties as an example, past causes of fires at cultural properties include arson, flying sparks, fireworks, etc., and exterior fires account for about 70% of the time. For this reason, there is a demand for reliable detection of fire causes not only indoors but also outdoors.

As a conventional technology for detecting arson at important cultural properties and the like, there is an arson detection system as described below (see, for example, Patent Document 1). The system according to Patent Document 1 includes a flame sensor having a flame detection unit, a human body sensor having a human body detection unit, a sensitivity setting unit that sets the sensitivity of the flame detection unit, a transmitting unit that transmits an intrusion signal when the human body detection unit detects a human body, and a receiving unit that receives the intrusion signal.

The system described in Patent Document 1 controls the sensitivity setting unit to switch to high sensitivity when an intrusion signal is received. If a flame is detected by the flame sensor, a fire signal is wirelessly transmitted to the receiver, and the receiver, having received the fire signal and the intrusion signal, determines that arson has occurred and transfers the arson signal to a mobile terminal.

As a result, even if the device is installed outdoors with the sensitivity set to low, false alarms caused by sunlight and other factors are reduced, and the manager carrying the mobile device is quickly notified that a fire has been detected.

JP 2004-303093 A

However, the conventional techniques have the following problems.
The system disclosed in Patent Document 1 targets arson and monitors for fires occurring outdoors in buildings where no one is usually present by increasing the sensitivity when a human body is detected. However, as described above, the cause of fire is not limited to "arson" but may also be "flying sparks" or "fireworks", and it is important to reliably detect exterior fires caused by all of these causes.

From this perspective, the system described in Patent Document 1 cannot perform arson detection with high sensitivity unless an intrusion signal is detected, and cannot reliably detect anticipated exterior fires.

In addition, when installing flame detectors outdoors, it is important to consider how to prevent false alarms caused by sunlight and how to reduce the effects of rainwater. Therefore, taking these factors into consideration, there is a strong need to establish a fire alarm system that is suitable for detecting fires on the exterior of buildings where no one is usually present.

The present invention has been made to solve the above problems, and aims to provide a fire alarm system suitable for detecting fires on the exterior of buildings that are usually unoccupied.

The fire alarm system according to the present invention comprises a flame detector that is installed outdoors of a building that is subject to fire monitoring and outputs a fire signal when it detects the occurrence of a fire; an alarm slave unit that is installed indoors of the building and outputs a wireless signal notifying that a fire has occurred in the building when it receives a fire signal from the flame detector; and an alarm master unit that is installed indoors of equipment away from the building that is subject to fire monitoring and where a building watchman is present and that alerts the watchman that a fire has occurred in the building by receiving the wireless signal output from the alarm slave unit, the flame detector and the alarm slave unit are supplied with power from an AC power source provided in the building, and the alarm master unit is supplied with power from an AC power source provided in the equipment, and when the alarm master unit installed indoors of the equipment and the alarm slave unit installed indoors of the building are geographically located within an allowable distance for direct communication by wireless signals, they communicate directly with each other, and when they are geographically located further away than the allowable distance for direct communication by wireless signals, they communicate via a repeater that is provided between the alarm master unit and the alarm slave unit and acts as a relay that transfers the wireless signal received from the alarm slave unit to the alarm master unit .

The present invention provides a fire alarm system suitable for detecting fires on the exterior of buildings that are usually unoccupied.

1 is a diagram showing an overall configuration including a fire alarm system according to a first embodiment of the present invention. 1 is an explanatory diagram showing an example of each component included in a fire alarm system in accordance with embodiment 1 of the present invention, together with a geographical arrangement. FIG. FIG. 2 is an explanatory diagram showing a specific example of a flame detector installed in a shrine in the first embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a fire alarm system according to the present invention will be described with reference to the drawings.
The fire alarm system of the present invention has the technical feature that a flame detector is installed outdoors of the building to be monitored, an alarm slave unit is provided indoors which receives a signal from the flame detector and transmits a wireless signal to the alarm master unit, and the flame detector and alarm slave unit are supplied with power via a wired connection.

Embodiment 1.
1 is a diagram showing an overall configuration including a fire alarm system according to a first embodiment of the present invention. The fire alarm system according to the first embodiment is configured to include M detection units 10(1) to 10(M) and a communication control unit 20.

The M detection units 10(1)-10(M) are installed in buildings to be monitored for fires, and have the function of wirelessly transmitting a fire signal indicating that a fire has been detected. Each of the M detection units 10(1)-10(M) has the same configuration, and in the following, unless there is a particular need to distinguish between them, they will be simply referred to as detection unit 10. Examples of buildings in which detection units 10 are installed include shrines, temples, castles, etc., which are cultural properties that are normally unoccupied.

On the other hand, the communication control unit 20 is located away from the building in which the detection unit 10 is installed, is installed in a facility where a watchman or the like is present, and has the function of wirelessly receiving the fire signal transmitted from the detection unit 10. Examples of facilities in which the communication control unit 20 is installed include a shrine office, a management center, etc.

The communication control unit 20 is configured to be able to communicate with an external device, a server 40, and L mobile terminals 50(1)-50(L), via a network 30 such as the Internet. Therefore, when the communication control unit 20 receives a fire signal, it can notify the external device that a fire has occurred by wireless signal.

Next, we will explain the specific configurations and functions of the detection unit 10 and the communication control unit 20, which are the main components of the fire alarm system according to the first embodiment.

First, the detection unit 10 will be described. The detection unit 10 is configured with a wireless alarm slave unit 11, N flame detectors 12(1)-12(N), and an AC power source 13. Each of the N flame detectors 12(1)-12(N) has the same configuration, and below, when there is no need to distinguish between them, they will simply be described as flame detectors 12.

The wireless alarm slave unit 11 is installed inside a building that is to be monitored for fires, and is supplied with power from an AC power source 13. On the other hand, the flame detector 12 is installed outside the building so that it can detect fires on the exterior of the building, and is supplied with power from the AC power source 13. Note that FIG. 1 illustrates an example in which power is supplied from the AC power source 13 to the flame detector 12 via the wireless alarm slave unit 11.

Here, in this embodiment 1, "outside the building" means a location other than the interior of the building itself, such as under the eaves or edges of the building, which is suitable for detecting fires on the exterior of the building.

Since the flame detector 12 is installed outside a building, it is desirable for it to have a waterproof function to prevent rainwater, etc. from entering the inside of the device. However, if the flame detector 12 is installed under an eaves or other location that is less susceptible to the effects of rainwater, etc., a waterproof function is not essential. Also, even if the flame detector 12 is to have a waterproof function, this can be achieved by adding a simple waterproof function instead of a complete waterproof function.

A wireless alarm slave unit 11 installed inside a building is connected by wire to each of N flame detectors 12(1) to 12(N) installed outside the building. When a flame detector 12 detects the occurrence of a flame, it outputs a detection signal to the wireless alarm slave unit 11.

When the wireless alarm slave unit 11 receives a detection signal from any of the flame detectors 12, it transmits a fire signal, indicating that a fire has occurred in the building being monitored, to the wireless alarm master unit 21 as a wireless signal.

Next, the communication control unit 20 will be described. The communication control unit 20 is configured with a wireless alarm master unit 21, an AC power source 23, and a receiver 24.

The wireless alarm master unit 21 is located away from the building to be monitored, installed inside the facility where a security guard is present, and is supplied with power from an AC power source 23. The receiver 24 is also installed inside the facility, connected to the wireless alarm master unit 21 by wire, and is supplied with power from the AC power source 23. Note that FIG. 1 shows an example in which power is supplied from the AC power source 23 to the receiver 24 via the wireless alarm master unit 21.

The wireless alarm master unit 21 receives a fire signal transmitted as a wireless signal from the wireless alarm slave unit 11 and determines that a fire has occurred in a building where no one is normally present. Furthermore, when the wireless alarm master unit 21 determines that a fire has occurred, the receiver 24 receives an activation signal from the wireless alarm master unit 21 and can notify an external device of the occurrence of a fire by sounding an alarm, displaying a display on a panel, etc. Furthermore, it can also transmit an alarm signal via the Internet communication network 30 to an external device to notify the external device that a fire has occurred in the building.

As a result, the server 40 and the mobile terminals 50(1)-50(L), which correspond to external devices, can receive the alarm signal via the Internet communication network 30 and can learn that a fire has occurred in a building that is under fire monitoring.

Based on the basic configuration shown in Figure 1 as described above, the system configuration including the specific geographical layout will be explained using Figure 2 as an example. Figure 2 is an explanatory diagram showing an example of each component included in the fire alarm system in embodiment 1 of the present invention, along with the geographical layout.

In Figure 2, Shrine 1 and Shrine 2 are shown as examples of buildings that are normally unoccupied, along with Shrine Office 3, which is located away from Shrine 1 and Shrine 2 and is a facility manned by security guards. In the example of Figure 2, Shrine 2 is located on a mountain several hundred meters away from Shrine Office 3, and Shrine 1 is located closer to Shrine Office 3 than Shrine 2.

Shrine 1 is provided with a detection unit 10(1), shrine 2 is provided with a detection unit 10(2), and shrine office 3 is provided with a communications control unit 20. Specifically, in shrine 1, an alarm sub-unit 11 is provided inside shrine 1, and two flame detectors 12(1) and 12(2) are provided outside under the eaves of shrine 1. Similarly, in shrine 2, an alarm sub-unit 11 is provided inside shrine 2, and two flame detectors 12(1) and 12(2) are provided outside under the eaves of shrine 2.

In addition, a wireless alarm master unit 21 and a receiver 24 are installed inside the shrine office 3.

The shrine 1 and the shrine office 3 are located relatively close to each other, and the wireless alarm slave unit 11 in the shrine 1 and the wireless alarm master unit 21 in the shrine office 3 are configured to be able to directly communicate wirelessly with each other.

On the other hand, as shown in Figure 2, the shrine 2 and the shrine office 3 are located relatively far apart, several hundred meters apart. Therefore, the wireless alarm slave unit 11 in the shrine 2 and the wireless alarm master unit 21 in the shrine office 3 cannot directly communicate wirelessly with each other. In such a case, it is possible to provide a repeater that acts as a relay, transferring the wireless signal received from the wireless alarm slave unit 11 to the wireless alarm master unit 21.

Specifically, a wireless repeater 60, not shown in FIG. 1, and an AC power source 63 for supplying power to the wireless repeater 60 are provided between the shrine 2 and the shrine office 3. By adopting such a configuration, the wireless alarm slave unit 11 in the shrine 2 and the wireless alarm master unit 21 in the shrine office 3 can wirelessly communicate with each other via the wireless repeater 60. If the wireless repeater 60 is installed outdoors, it is recommended that it be placed in a waterproof box made of resin, for example.

Next, we will explain the case where a flame detector 12 is installed in a shrine, which is an example of a building that is a cultural asset. Figure 3 is an explanatory diagram showing a specific example of installing a flame detector 12 in a shrine in embodiment 1 of the present invention.

Shrines and other places of worship generally have roofs with large eaves, and flame detectors 12 are attached to the eaves of these roofs. As shown in FIG. 3, by attaching flame detectors 12(1) and 12(2) to the eaves, external light such as sunlight is not allowed to enter flame detectors 12(1) and 12(2), and false alarms are prevented. However, to more reliably block external light, a light-shielding cover may be attached to flame detectors 12(1) and 12(2) before they are installed under the eaves.

As shown in Figure 3, in the case of shrines with raised floor structures, the flame detectors 12(3) and 12(4) may be installed under the veranda (under the floor) rather than under the eaves. Even in this case, as long as the flame detectors 12(3) and 12(4) are installed facing the ground (downward), false alarms due to external light can be prevented. Furthermore, the flame detectors 12(3) and 12(4) installed under the veranda (under the floor) can quickly and reliably detect the building catching fire due to arson or sparks flying under the veranda.

In this way, the flame detectors 12(1)-12(4) are installed in inconspicuous locations in the building to be protected, so as not to spoil the building's aesthetic appearance. Also, as shown in FIG. 3, the flame detectors 12(1)-12(4) are installed at multiple locations at different heights in the building's height direction, eliminating blind spots and enabling reliable detection of fires.

Furthermore, the flame detectors 12(1) and 12(2) installed under the eaves are installed so that the field of view of the sensor unit faces toward the center of the building. This is to prevent them from detecting flames from lighters or other objects held by tourists who come to see the building, and to enable quick and reliable detection of fire in the building caused by arson or sparks spreading.

It is desirable to mount multiple flame detectors 12 around the entire perimeter of the building so that the monitoring fields of two or more flame detectors 12 overlap each other so that the entire building can be monitored. Note that instead of mounting flame detectors 12 directly on the building, a pole that is taller than the building may be installed near the building, and flame detectors 12 may be mounted on the pole so that the roof of the building can be monitored.

If we summarize the characteristics of a fire alarm system having the layout shown in Figure 2 or Figure 3, it has the following configurations 1 to 4 and can achieve effects 1 to 4.

(Configuration 1) Flame detector 12 is provided under the eaves of shrine 1 or shrine 2 (outside the building).
(Effect 1) By adopting a configuration in which the flame detector 12 is placed outside the building in this way, it is possible to make it less susceptible to the effects of rainwater. In addition, by adopting a configuration in which the flame detector 12 is placed outside the shrine 1 or shrine 2, it is possible to more reliably detect fires on the exterior.

(Configuration 2) A wireless alarm sub-unit 11 is provided within the building which is shrine 1 or shrine 2, which receives via wired connection the detection signal transmitted from a flame detector 12 and transmits a fire signal as a wireless signal to a wireless alarm parent unit 21 to notify that a fire has occurred in the building.
(Effect 2) By adopting a configuration in which the flame detector 12 is connected to the wireless alarm sub-unit 11 by wire and AC power can be supplied, unlike wireless flame detectors, a stable power supply can be established and reliable operation can be guaranteed without concerns about battery life or battery replacement.

(Configuration 3) A wireless alarm master unit 21 that receives wireless signals is provided in a shrine office 3 away from the building that is shrine 1 or 2.
(Effect 3) By adopting a configuration in this way that allows wireless signals notifying of a fire to be received at a remote location, even if there is no one present at Shrine 1 or Shrine 2, which are cultural assets, the wireless signal notifying of a fire can be received by wireless alarm master unit 21 in office 3, and the administrator in office 3 can be reliably notified that a fire has occurred at the cultural asset.

(Configuration 4) If the distance between the wireless alarm parent unit 21 and the wireless alarm child unit 11 is greater than the allowable distance for direct wireless communication, a wireless repeater 60 capable of relaying wireless communication is provided between the wireless alarm parent unit 21 and the wireless alarm child unit 11.
(Effect 4) By utilizing this type of relay function, a wireless communication system can be easily constructed via the wireless repeater 60, even if the wireless alarm parent unit is installed at a distance where it cannot directly receive wireless signals from the wireless alarm child unit 11.

According to the fire alarm system of the present embodiment 1, by combining configurations 1 to 3, effects 1 to 3 can be obtained. Furthermore, according to the fire alarm system of the present embodiment 1, by further including configuration 4, effect 4 can be obtained. As a result, a fire alarm system suitable for detecting fires on the exterior of buildings where no one is usually present can be realized.

1, 2 Shrine (building), 3 Shrine office (equipment), 10 Detection unit, 11 Wireless alarm slave unit (alarm slave unit), 12 Flame detector, 13 AC power source, 20 Communication control unit, 21 Wireless alarm master unit (alarm master unit), 23 AC power source, 24 Receiver, 30 Internet communication network, 40 Server, 50 Mobile terminal, 60 Wireless repeater, 63 AC power source.

Claims (2)

A flame detector that is installed outside a building to be monitored for fire and outputs a fire signal when it detects the occurrence of a fire;
an alarm slave unit that is installed inside the building and that outputs a wireless signal notifying that a fire has occurred in the building when the fire signal is received from the flame detector;
an alarm master unit that is installed away from the building that is the subject of fire monitoring , indoors of equipment where a watchman of the building is present , and that receives the wireless signal output from the alarm slave unit to alert the watchman that a fire has occurred in the building,
The flame detector and the alarm slave unit are supplied with power from an AC power source installed in the building,
The alarm master unit is supplied with power from an AC power source provided in the facility ,
The alarm master unit installed indoors of the facility and the alarm slave unit installed indoors of the building are
communicate directly with each other if they are geographically located within an acceptable distance for direct communication by said radio signals;
When the alarm units are geographically located at a distance greater than the allowable distance at which direct communication by wireless signals can be performed, communication is performed via a repeater that is provided between the alarm master unit and the alarm slave unit and acts as a relay that transfers the wireless signal received from the alarm slave unit to the alarm master unit.
Fire alarm system. The flame detector is configured as a plurality of flame detectors,
Each of the plurality of flame detectors installed outdoors of the building includes:
The sensors are installed at different heights in the height direction of the building,
or,
are mounted around the entire perimeter of the building with overlapping surveillance fields of view;
2. The fire alarm system according to claim 1, wherein the alarm slave unit outputs the wireless signal notifying that a fire has occurred in the building when the alarm slave unit receives the fire signal from any of the plurality of flame detectors .