TWM540352U - In-building fire protection equipment monitoring system - Google Patents

Description

Monitoring system for fire equipment in buildings

The novel system is related to the fire protection equipment monitoring system of the building, in particular to a monitoring system for the fire equipment in the building using the escape light device of the building as a wireless transmission node.

In addition to the emphasis on functionality and appearance, modern building construction combines the management and monitoring of "technical" auxiliary buildings to form so-called "smart buildings". Modern "smart buildings" not only create a comfortable and convenient working or living environment under the premise of "energy saving", especially when there is an accident, the intelligent building monitoring and integration system can play the most efficient disaster response system. It can automatically start the functions of disaster prevention, self-rescue, emergency notification and search and rescue evacuation to minimize the damage of personal property; but the smart building is not just disaster prevention, but in the ordinary circumstances, IT is actually deeper into life applications. For example, it can improve the safety of buildings, avoid various problems caused by human negligence, detect faults in public facilities in advance, reduce the expenditure on manpower for management and management, and make the life of users more convenient.

Perceptual, interconnected and communicative thinking is the biggest difference between "smart buildings" and traditional buildings. "Smart buildings" have the following: initiative to present the complete status of building operations, immediate warning risks, and assistance in management. The ability to make the best decisions, including perceptualization, is to install sensors in the building's building environment and equipment, and collect building operational data at any time. The interconnection is through the Internet of Things (IOT). Internet of Things) brings together relevant data to the management information platform.

In recent years, "smart buildings" have adopted a large number of "smart monitoring and integration systems", which often include the following five subsystems: such as disaster prevention management system, CCTV (Closed-Circuit Television; CCTV) monitoring system, access control security system and parking management system. However, how to integrate these heterogeneous systems and process large amounts of data (especially CCTV films) in real time requires a "smart building monitoring and integration system" with a large system and wired transmission.

However, once the building has an accident such as a fire or an earthquake, the building's power supply and huge lines may be cut off or damaged, which will cause the traditional "Smart Building Monitoring and Integration System" to lose some functions, especially for the most If the important disaster prevention management system fails to function properly in the event of a disaster, it will lead to major casualties of the household's property.

In addition, Bluetooth BT and ZigBee are a kind of wireless LAN (Wireless PAN), and its technical and application aspects have gradually matured, especially the most important Bluetooth Low Energy feature of Bluetooth 4.0, in low power mode conditions. In the meantime, it has been widely used in the loading device and the sensing component. It can communicate wirelessly in a small range, but cannot transmit the data capacity like a video, and can only transmit simple digital signal data.

According to current building codes and building fire safety regulations, the escape light device is an essential safety device for each building and must be installed at least every 25 meters, usually in spacious walkways, stairwells and safe escape exits. At the same time, the signal transmission is not easy to be obstructed; in addition, the regulations also stipulate that the device will be lit by the usual power supply on weekdays, but in the event of power failure or power failure, it can be automatically switched to emergency power supply lighting, and an emergency power supply (such as an uninterruptible power system) must be set up. ) and ensure that its operation time should be maintained for at least 90 minutes, so when there is a power outage in the building, there is no doubt that the power supply is insufficient or interrupted, which is very suitable as a wireless transmission node of the intelligent building monitoring system, making the intelligent building The monitoring system can continue to operate.

In addition, the safe escape is the first layer of smart building. Among the five subsystems of the traditional “smart monitoring and integration system”, the disaster prevention management system is the most important subsystem. Therefore, there are many configurations on each floor of the building. Fire-fighting equipment, such as gas detection alarms for detecting gas, carbon monoxide, or carbon dioxide concentrations, temperature detection alarms for detecting indoor temperatures, smoke detection alarms for detecting indoor smoke concentrations, Automatic sprinklers for fire extinguishing, smoke exhaust systems for exhausting smoke, etc., can increase the mastery of environmental changes and will achieve the two goals of prevention and harm reduction.

However, when the fire protection equipment of the above-mentioned buildings is in an abnormal state for the environmental change or the detection operation is abnormal, the relevant detection data is a simple digital data format, and all of the small-range, low-power wireless communication can be performed through BT and ZigBee. Even if combined with the existing escape light device of the building as the wireless transmission node of the intelligent building monitoring system, the cloud monitoring database of the intelligent building fire protection equipment can be further established, and the security personnel, residents, rescuers, etc. The disaster prevention management information platform can instantly inform the latest disaster distribution and disaster distribution information. Even in the event of a fire or earthquake disaster, the fire equipment monitoring system can continue to operate and effectively improve the tradition. The absence of the "Smart Building Monitoring Integration System".

For example, in 2014, two major public security incidents occurred in Taiwan - the Kaohsiung City gas explosion and the new store gas explosion incident. The Taiwan society still has the embers still in existence. The Kaohsiung gas explosion incident is from July 31 to August 1, 2014. During the incident of petrochemical gas explosions, the public reported that there was a suspected gas leak. Although the rescuers had come to the disposal, the source and gas types could not be confirmed, resulting in a series of explosions in the area after a few hours. The death of the person and the injury of 321 people; as for the Xinbao City Yongdian Yongkang Community, a gas explosion occurred on August 15, 2014, causing the tragedy of 2 deaths and 69 households. In the early days of these two major gas explosions, people have reported that they suspected that there is gas leakage and odor. However, because the smell is permeated in the public space, the relevant personnel cannot confirm the source of the actual leakage of the odor and cause disasters afterwards.

Especially for the new store gas explosion incident, the management committee alleged that although it was notified to Xinxin Gas Company about the smell on the 14th, the tester of Xinxin was only present for 10 minutes on the same day, only in the basement test, and did not check the building layer by layer. It is an indisputable fact that the public areas, or to the households, are carefully detected and left, resulting in the fact that the source of gas leakage has not been confirmed to be located in a residential building on the third floor of Building A.

In view of the lessons of the new store explosion, if various fire-fighting equipment (such as gas detection alarms, temperature detection alarms or smoke detection alarms) can be installed in the public areas of the buildings and in the households. Through the escape light set in the spacious walkway, stairwell and safe escape exit as the wireless transmission node of the intelligent building monitoring system, the cloud monitoring database of the intelligent building fire protection equipment can be further established. For example, when the gas detection alarm on a certain floor of the building detects that the indoor gas concentration on a certain floor of the building is too high, the warning can be obtained at the first time, and the management room can confirm the source of the gas leakage at the first time. At the floor location, even if the household is not in the house at the time, the gas leakage phenomenon can be effectively solved immediately, avoiding the problem of subsequent public safety.

In the case of a fire in a building, in order to make the rescuers more successful in the rescue operation, the smoke exhaust system in the building must be in the ON state. However, due to the rescue workers in the smoky buildings, One by one to visually check whether the smoke exhaust system on each floor is in the starting state, so it is impossible to give the rescuer or the trapped person the best disaster relief suggestion route or escape route, which invisibly improves the difficulty of disaster relief and escape, how to The intelligent building fire protection equipment cloud monitoring database to control the operation status (ON-OFF) of the smoke exhaust system on each floor to reduce the casualties of the rescuers is also one of the problems to be solved by the present invention.

The purpose of the present invention is to provide a monitoring system for fire-fighting equipment in a building, which mainly uses an escape light device of a building as a wireless transmission node, so that various fire-fighting equipment in the building can be monitored at any time to obtain the most immediate measures. .

Another object of the present invention is to provide a monitoring system for fire-fighting equipment in a building, which mainly uses an escape light device of a building as a wireless transmission node, wherein the detection signals of each fire-fighting equipment include identification codes of each floor (Identification No.) In order to enable rescuers to conduct search and rescue operations, they can grasp the location and operation status of each fire-fighting equipment and improve the safety of disaster relief.

The reason is that, in order to achieve the foregoing objective, a monitoring system for fire protection equipment in a building according to the present invention is suitable for use with a building monitoring information cloud server and a plurality of fire fighting equipment disposed in a building, the monitoring system includes The plurality of detection modules are respectively disposed in the fire fighting device and have a signal transmitting unit capable of emitting a detection signal; the plurality of escape light devices are disposed in an escape passage, a stairwell or an escape exit on each floor of the building, And a receiving unit coupled to the signal transmitting unit, an information transmitting unit coupled to the receiving unit signal, and an uninterruptible unit for supplying power required by the receiving unit and the information transmitting unit;

After receiving the detection signal of the signal transmitting unit, the receiving unit determines at least the detection information of the fire fighting device, and converts the detection information into a notification signal and transmits the information to the information transmitting unit; the information transmitting unit receives the notification signal After that, the detection information is uploaded to the building monitoring information cloud server and continuously updated.

Preferably, the fire fighting equipment in the building is a gas detection alarm, a temperature detection alarm, a smoke detection alarm, an emergency lighting system, an uninterruptible power unit, a fire extinguishing device, a smoke exhaust system, a fire alarm system, Broadcast system, water tank or fire hydrant.

Preferably, the detection information of the fire-fighting equipment includes gas concentration, temperature level, smoke concentration, water pressure level, volume level, voltage level, and whether the electronic signal is activated (ON-OFF).

Preferably, the building monitoring information cloud server can transmit the detection information to the management room of the building, the fire disaster relief center, the portable device of the security personnel, the portable device of the on-site rescue commander, or the site. Portable device for rescuers.

Preferably, the building monitoring information cloud server has an escape plan for each floor of the building, for the trapped person to download the escape plan of the building monitoring information cloud server to the portable type by the escape light device Device.

Preferably, the signal connection between the signal transmitting unit of each detecting module and the receiving unit of each of the emergency light devices is communication using Bluetooth protocol communication, Wi-Fi protocol communication, or ZigBee protocol.

Preferably, the signal connection between the information transmitting unit and the building monitoring information cloud server is communication using Wi-Fi protocol, 3G, 4G, 5G wireless protocol.

Preferably, the detection information of each fire-fighting device includes each floor code identity (Identification No.), and the receiving unit of each of the escape lamp devices receives the detection signal, so that the detection information includes the floor location of the fire-fighting device.

Preferably, the portable device is a smart phone, a tablet computer or a wearable device with a wireless network connection function.

Preferably, the detecting module further has an uninterruptible power unit, and the uninterruptible power unit provides power required for the detecting module and the signal transmitting unit to operate when the building is powered off.

With regard to the techniques, means, and other functions of the present invention for achieving the above objects, ten preferred embodiments are described in detail with reference to the drawings.

Referring to FIG. 1 to FIG. 3 , a monitoring system for fire protection equipment in a building provided by the first embodiment of the present invention is applicable to a building monitoring information cloud server 10 and a plurality of fires disposed in the building 200 . The device 20 is used. In this embodiment, the fire fighting device 20 is a gas detecting alarm 20A for detecting gas, carbon monoxide, or carbon dioxide concentration. The monitoring system includes:

The plurality of detection modules 30 are respectively disposed in the fire-fighting device 20 and have a signal transmitting unit 31 capable of emitting a detection signal 311. In this embodiment, when the fire-fighting device 20 (ie, the gas detecting alarm 20A) detects When the indoor gas concentration is higher than the set value, in addition to an alarm sound, the signal transmitting unit 31 of the detecting module 30 sends a detecting signal 311; in addition, the detecting module 30 has an uninterruptible unit. 33. The uninterruptible power unit 33 provides power required by the detecting module 30 and the signal transmitting unit 31 to operate when the building is powered off.

The plurality of escape light devices 40 are disposed in the escape passage, the stairwell or the escape exit of each floor of the building 200, and have a receiving unit 41 coupled to the signal transmitting unit 31 and a signal coupled to the receiving unit 41. The information transmitting unit 42 and an uninterruptible power unit 44 for the receiving unit 41 and the information transmitting unit 42 to operate the required power; in this embodiment, the emergency light unit 40 has an indicator light 43.

After receiving the detection signal 311 of the signal transmitting unit 31, the receiving unit 41 determines the detection information 411 of the fire fighting device 20, and converts the detection information 411 into a notification signal 412 and transmits the information to the information transmitting unit 42. In the example, the detection information 411 of each fire-fighting device 20 includes each floor code identity (Identification No.), so that the receiving unit 41 of each of the escape lamp devices 40 receives the detection signal 411, so that the detection information 411 includes the fire protection. The location of the floor of the device 20; in addition, the signal connection between the signal transmitting unit 31 of each detecting module 30 and the receiving unit 41 of each of the emergency light devices 40 is using Bluetooth protocol communication, Wi-Fi protocol communication, or ZigBee. Agreement communication, but not limited to this.

After receiving the notification signal 412, the information transmitting unit 42 uploads the detection information 411 to the building monitoring information cloud server 10, and continuously updates; in this embodiment, the information transmitting unit 42 and the building monitoring The signal connection between the information cloud server 10 is communication using Wi-Fi protocol communication, 3G, 4G, 5G wireless protocol, but not limited thereto.

In addition, in this embodiment, the building monitoring information cloud server 10 can transmit the detection information 411 to the management room 51 of the building, the fire disaster relief center 52, the portable device 53 of the on-site rescue commander, and the on-site rescue The portable device 54 of the person, or the portable device 55 of the security personnel, is not limited thereto, wherein the portable device is a smart phone, a tablet computer or a wearable device with wireless network connection function. .

The above description is the configuration description of each main component of the first embodiment of the present invention. The mode of operation of this new model is explained below. Please also cooperate with FIG. 2 and FIG. 4 to detect the gas leakage of the building 200 to help explain the operation process of the building monitoring system as follows.

When gas leakage occurs on the 7th and 8th floors of the building 200, and the fire-fighting equipment 20 (ie, the gas detection alarm 20A) located on the 7th and 8th floors detects that the indoor gas concentration is higher than the set value, The signal transmitting unit 31 of the detecting module 30 on the 7th and 8th floors sends a detecting signal 311, and the escape light device 40 disposed on the 7th and 8th floors respectively communicates with the detecting module 30 of the corresponding floor. Therefore, the escape light device 40 disposed on the 7th and 8th floors receives the detection signal 311, and finally transmits the detection information 411 to the building monitoring information cloud server through the operation of the receiving unit 41 and the information transmitting unit 42. The building monitoring information cloud server 10 transmits the detection information 411 to the management room 51 of the building (of course, it can also be transmitted to the fire rescue center 52, the portable device of the on-site rescue commander 53 , The portable device 54 of the on-site rescue personnel, or the portable device 55) of the security personnel, so that the security personnel of the building management room can immediately know that the gas leaks on the 7th and 8th floors of the building 200 simultaneously In order to protect the personnel to perform the corresponding movement Work. Accordingly, the novel application of the building's escape light device as a wireless transmission node enables the fire protection devices 20 in the building 200 to be monitored at any time to achieve the most immediate action.

It is worth noting that, according to current building regulations and building fire safety regulations, the escape light device 40 is an essential safety device for each building, and must be provided at least every 25 meters, usually in a spacious stairwell. The walkway and the safe escape exit are high, and the signal transmission is not easy to be obstructed. In addition, the regulations also stipulate that the device will be lighted by the usual power supply on weekdays, but in the event of power failure or power failure, it can be automatically switched to emergency power supply lighting. (such as uninterruptible power unit 44 or built-in battery), and ensure that its operating time should be maintained for at least 90 minutes. Therefore, the present invention particularly utilizes the necessary emergency light device 40 in the building 200 as a wireless transmission node, and the emergency light unit 40 is provided with an uninterruptible power unit 44 to provide backup power when the escape light device 40 is activated. Therefore, in the event of a power outage in the building 200, there is no doubt that the power supply is insufficient or interrupted, and it is very suitable as an IoT node of the building 200 monitoring system, so that the new monitoring system can operate.

On the other hand, the present invention can provide an escape plan for each floor of the building 200 in the building monitoring information cloud server 10 for the trapped person to download the building monitoring information cloud by the escape light device 40. The escape plan in the server 10 to the portable device (ie, a smart phone, a tablet or a wearable device with a wireless network connection function), so that the first time the person in the building 200 is in an emergency Was able to escape smoothly.

Furthermore, the building monitoring system using the emergency light device 40 as a wireless transceiver node does not require additional wiring or space for the old building or the new building, nor does it affect or destroy the interior decoration and facilities of the original building. It is only necessary to assemble the receiving unit 41 and the information transmitting unit 42 on the old emergency light device 40 and the detecting module 30 on the fire fighting device 20, which is cost, flexibility, convenience and networking for the construction. Both have considerable advantages and potential.

Referring to FIG. 2 and FIG. 5, a monitoring system for fire protection equipment in a building provided by the second embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200. The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as a group of the second embodiment. The state and function are the same as those in the first embodiment, so the details are not described again. The difference in the second embodiment lies in:

The fire-fighting device 20 is a temperature detecting alarm 20B for detecting the indoor temperature, and the detecting module 30 of the fire-fighting device 20 detects the ambient temperature in the vicinity thereof at any time, and detects that the ambient temperature is higher than the setting. When the value is determined, it is determined that the ambient temperature is too high, and a fire may have occurred. The temperature detecting alarm 20B outputs the detection signal 311 (including the temperature signal) to monitor the temperature change trend of the fire floor of each floor of the building.

Referring to FIG. 2 and FIG. 6 , a monitoring system for fire protection equipment in a building provided by the third embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as a group of the third embodiment. The state and function are the same as those of the first embodiment, so the details of the third embodiment are not described here:

The fire-fighting device 20 is a smoke detecting alarm 20C for detecting the concentration of smoke in the room, and the detecting module 30 of the fire-fighting device 20 detects that the indoor visibility is lower than the set value, and determines that smoke is generated indoors. The detection module 30 outputs the detection signal 311 to monitor whether there is smoke in the room.

Referring to FIG. 2 and FIG. 7 , a monitoring system for fire protection equipment in a building provided by the fourth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, and an escape lamp device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as shown in the fourth embodiment. The state and function are the same as those in the first embodiment, so the details are not described again. The fourth embodiment is different in:

The fire extinguishing device 20 is a smoke exhausting system 20D, and the detecting module 30 is disposed at the exhausting path 21D of the exhausting system 20D. When the exhausting system 20D is activated, the detecting module 30 senses the exhausting path. When the air pressure is higher than the set value, it is determined that the exhaust system 20D is activated, and the detecting module 30 outputs the detection signal 311 to monitor whether the exhaust system 20D is in an active state.

Referring to FIG. 8 , when the fire fighting device 20 is a smoke exhaust system 20D, the detection module 30 can be disposed in the smoke exhausting path of the exhaust system 20D, and can be disposed in the exhaust system. 20D windmill 22D (the damper is also available), when the exhaust system 20D is activated, the detecting module 30 senses whether the windmill 22D is activated. When the speed of the windmill 22D is higher than the set value, it is determined that the exhaust system 20D is activated. The detecting module 30 outputs the detecting signal 311 to monitor whether the exhaust system 20D is in an active state.

Referring to FIG. 2 and FIG. 9 , a monitoring system for fire protection equipment in a building provided by the fifth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as a group of the fifth embodiment. The state and function are the same as those in the first embodiment, so the details are not described again. The difference in the fifth embodiment lies in:

The fire-fighting device 20 is an escape light device 40, and the detection module 30 is disposed inside the escape light device 40 to self-detect whether the voltage of the uninterruptible power unit 44 of the emergency light device 40 is sufficient (or detection indication) Whether the brightness of the lamp 43 is sufficient or not), when the voltage value of the uninterruptible power unit 44 is lower than the set value, the escape lamp device 40 is determined to be a defective product to be repaired, and the detection module 30 outputs the detection signal 311 to monitor the Whether the escape light device 40 can operate normally. If it is unable to move, it can be immediately notified through the monitoring system, and immediately notify the fire maintenance service provider to replace the defective product, improve the shortcomings that traditionally need to wait until the annual fire inspection of the building, and better protect the public safety of the building. .

Referring to FIG. 2 and FIG. 10 , a monitoring system for fire protection equipment in a building provided by the sixth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, and an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as shown in the sixth embodiment. The state and the effect are the same as those of the first embodiment, so the description of the sixth embodiment is not repeated.

The fire extinguishing device 20 is a fire extinguishing device (this embodiment is an example of an automatic sprinkler 20E), and the detecting module 30 is disposed inside the water tank 21E of the automatic sprinkler 20E, and can be detected at any time in the water tank 21E. If the water level in the water tank 21E is lower than the position set by the inspection module 30, the water quantity is determined to be insufficient, and the detection module 30 outputs the detection signal 311 to monitor the water volume in the water tank 21E. It is ensured that the automatic sprinkler 20E has sufficient water to be ejected when it is actuated.

Referring to FIG. 2 and FIG. 11 , a monitoring system for fire protection equipment in a building provided by the seventh embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, as shown in the seventh embodiment. The state and function are the same as those of the first embodiment, so the details of the seventh embodiment are not described here:

The fire-fighting device 20 is an emergency lighting system 20F, and the detecting module 30 is disposed inside the emergency lighting system 20F to detect the voltage level in the emergency lighting system 20F at any time, that is, to detect the emergency lighting system 20F at any time. When the voltage of the internal battery is lower than the set value, the emergency lighting system 20F is determined to be a product to be repaired, and the detecting module 30 outputs the detecting signal 311 to monitor the emergency lighting system. Can 20F operate normally?

Referring to FIG. 2 and FIG. 12, a monitoring system for fire protection equipment in a building provided by the eighth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200. The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, which is a group of the eighth embodiment. The state and function are the same as those in the first embodiment, so the details are not described again. The difference in the eighth embodiment lies in:

The fire-fighting device 20 is a fire alarm system 20G, and the detection module 30 is disposed inside the fire alarm system 20G to detect the volume of the alarm when the fire alarm system 20G is alarmed or whether the electronic signal starts to operate when activated (ON) -OFF), when the volume of the fire alarm system 20G is lower than the set value or the electronic signal is not activated, the fire alarm system 20G is determined to be a product to be repaired, and the detection module 30 outputs the detection signal 311 to Monitor whether the fire alarm system 20G can operate normally.

Referring to FIG. 2 and FIG. 13 , a monitoring system for fire protection equipment in a building provided by the ninth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, and an escape lamp device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, which is a group of the ninth embodiment. The state and the effect are the same as those of the first embodiment, and therefore will not be described again. The difference of the ninth embodiment lies in:

The fire fighting device 20 is a broadcast system 20H, and the detecting module 30 is disposed inside the broadcast system 20H to detect the volume of the broadcast system 20H when the broadcast is performed. When the broadcast system 20H is activated, the volume is lower than the setting. When the value is determined, the broadcast system 20H is determined to be a product to be repaired, and the detection module 30 outputs the detection signal 311 to monitor whether the broadcast system 20H can operate normally.

Referring to FIG. 2 and FIG. 14 , a monitoring system for fire protection equipment in a building provided by the tenth embodiment of the present invention is also applicable to a building monitoring information cloud server 10 and a plurality of buildings in the building 200 . The fire-fighting device 20 is used. The monitoring system also includes a plurality of detection modules 30 disposed in the fire-fighting device 20, and an escape light device 40 having a receiving unit 41, an information transmitting unit 42, and an uninterruptible power unit 44, which is a group of the tenth embodiment. The state and the effect are the same as those of the first embodiment, and therefore will not be described again. The difference of the ninth embodiment lies in:

The fire extinguishing device 20 is a fire hydrant 20I, and the detecting module 30 is disposed inside the fire hydrant 20I to detect the water pressure level of the fire hydrant 20I at any time. When the water pressure of the fire hydrant 20I is lower than a set value Then, the fire hydrant 20I is determined to be malfunctioning, and the detecting module 30 outputs the detection signal 311 to monitor whether the fire hydrant 20I can operate normally.

In view of the above, the above embodiments and drawings are only preferred embodiments of the present invention, and the scope of the novel implementation cannot be limited thereto, that is, the equal changes and modifications made by the present invention in accordance with the scope of the present patent application are all It should be within the scope covered by this new patent.

10‧‧‧Building Monitoring Information Cloud Server
200‧‧‧ buildings
20‧‧‧Fire fighting equipment
20A‧‧‧Gas Detection Alarm
20B‧‧‧Temperature Detection Alarm
20C‧‧‧Smoke detection alarm
20D‧‧‧ smoke exhaust system
21D‧‧‧Exhaust path
22D‧‧‧Windmill
20E‧‧‧Automatic sprinkler
21E‧‧ ‧ water tank
20F‧‧‧Emergency lighting system
20G‧‧‧Fire Alarm System
20H‧‧‧Broadcast
20I‧‧‧ fire hydrant
30‧‧‧Test module
31‧‧‧Signal launch unit
311‧‧‧Detection signal
33‧‧‧Continuous power unit
40‧‧‧Escape light device
41‧‧‧ Receiving unit
411‧‧‧Location Information
412‧‧‧Notification signal
42‧‧‧Information launching unit
43‧‧‧ indicator light
44‧‧‧Continuous power unit
51‧‧‧Management room of the building
52‧‧‧Fire Disaster Relief Center
53‧‧‧ Portable device for on-site rescue commander
54‧‧‧ Portable devices for on-site rescuers
55‧‧‧ Portable devices for security personnel

Figure 1 is a schematic view of a first embodiment of the present invention. Figure 2 is a block diagram of the first embodiment of the present invention. Figure 3 is a side view of the first embodiment of the present invention. Figure 4 is a side elevational view of the first embodiment of the present invention showing the status of multiple floors. Figure 5 is a schematic view of a second embodiment of the present invention. Figure 6 is a schematic view of a third embodiment of the present invention. Figure 7 is a schematic view of a fourth embodiment of the present invention. Fig. 8 is a schematic view showing another arrangement state of the fourth embodiment of the present invention. Figure 9 is a schematic view of a fifth embodiment of the present invention. Figure 10 is a schematic view of a sixth embodiment of the present invention. Figure 11 is a schematic view of a seventh embodiment of the present invention. Figure 12 is a schematic view of an eighth embodiment of the present invention. Figure 13 is a schematic view of a ninth embodiment of the present invention. Figure 14 is a schematic view of a tenth embodiment of the present invention.

10‧‧‧Building Monitoring Information Cloud Server

200‧‧‧ buildings

51‧‧‧Management room of the building

52‧‧‧Fire Disaster Relief Center

53‧‧‧ Portable device for on-site rescue commander

54‧‧‧ Portable devices for on-site rescuers

55‧‧‧ Portable devices for security personnel

Claims (10)

A monitoring system for a fire-fighting equipment in a building is suitable for use with a building monitoring information cloud server and a plurality of fire-fighting equipment disposed in a building, the monitoring system comprising: a plurality of detecting modules, respectively configured in the fire-fighting equipment, And having a signal transmitting unit capable of emitting a detection signal; a plurality of escape light devices disposed in an escape passage, a stairwell or an escape exit on each floor of the building, and having a receiving unit coupled to the signal transmitting unit, An information transmitting unit coupled to the receiving unit signal, and an uninterruptible unit for driving the receiving unit and the information transmitting unit; the receiving unit receiving the detection signal of the signal transmitting unit, at least determining the The detection information of the fire fighting device is converted into a notification signal and transmitted to the information transmitting unit; after receiving the notification signal, the information transmitting unit uploads the detection information to the building monitoring information cloud server. And keep updating. The fire protection equipment monitoring system in the building according to claim 1, wherein the fire protection equipment in the building is a gas detection alarm, a temperature detection alarm, a smoke detection alarm, an emergency lighting system, and an uninterrupted power supply. Units, fire-fighting equipment, smoke extraction systems, fire alarm systems, broadcast systems, water tanks or fire hydrants. The monitoring system for fire-fighting equipment in a building as claimed in claim 1, wherein the fire-fighting equipment detection information includes gas concentration, temperature level, smoke concentration, water pressure level, volume level, voltage level, and whether the electronic signal starts to operate ( ON-OFF). The monitoring system for fire protection equipment in a building according to claim 1, wherein the building monitoring information cloud server can transmit the detection information to the management room of the building, the fire disaster relief center, and the portable device of the security personnel. Portable devices for on-site rescue commanders or portable devices for on-site rescuers. The monitoring system for fire protection equipment in a building according to claim 1, wherein the building monitoring information cloud server has an escape plan for each floor of the building for the trapped person to download the building by the escape light device The monitoring plan of the cloud server's escape plan to the portable device. The monitoring system for fire-fighting equipment in a building according to claim 1, wherein the signal connection between the signal transmitting unit of each detecting module and the receiving unit of each of the emergency light devices is using Bluetooth protocol communication and Wi-Fi protocol. Communication, or ZigBee protocol communication. The monitoring system for fire protection equipment in a building according to claim 1, wherein the signal connection between the information transmission unit and the building monitoring information cloud server is using Wi-Fi protocol communication, 3G, 4G, 5G wireless protocol. communication. The monitoring system for fire-fighting equipment in a building according to claim 1, wherein the detection information of each fire-fighting equipment includes an identification number of each floor, and after receiving the detection signal, each receiving unit of the escape light device receives the detection signal. The detection information is included in the floor location of the fire fighting equipment. The monitoring system for fire protection equipment in a building according to claim 4 or 5, wherein the portable device is a smart phone, a tablet computer or a wearable device with a wireless network connection function. The monitoring system for fire-fighting equipment in a building as claimed in claim 1, wherein the detecting module further comprises an uninterruptible power unit, wherein the uninterruptible power unit provides the detecting module and the signal transmitting unit to operate when the building is powered off The power required.