TWI729838B - Intelligent fire-fighting equipment monitoring system and monitoring method thereof - Google Patents

Abstract

An intelligent fire-fighting equipment monitoring system, which includes: fire-fighting equipment, equipment recording module, circuit board, monitoring module, processing module and data transmission module. The equipment recording module is assembled at one end of the fire-fighting equipment, and the circuit board is arranged on In the accommodating space, the monitoring module is arranged on the circuit board, the monitoring module is electrically connected to the power supply module, the pressure detection unit detects the pressure data of the gas or liquid in the fire fighting equipment, and the power detection unit detects the power supply mode Group’s power data, the storage unit receives pressure data and power data, the data transmission module is electrically connected to the processing module, and the data transmission module transmits the pressure data and power data to the monitoring database; thus, the present invention uses the equipment recording module The setting of the group and monitoring module is to effectively manage the fire-fighting equipment and control the validity period of the fire-fighting equipment.

Description

Intelligent fire-fighting equipment monitoring system and monitoring method thereof

The invention relates to a fire-fighting equipment system, in particular to an intelligent fire-fighting equipment monitoring system and a monitoring method thereof.

According to this, in daily life, various disasters occur continuously, and among them, fires occur most frequently. When faced with a fire, the general public is usually helpless and can only rely on the rescue of firefighters. However, firefighters are also physical bodies. When facing a fire, they can only rely on the orders issued by the commander or the divisional commander to effectively reduce casualties and property losses.

Existing firefighting units’ mastery of disaster relief equipment and accessories is mainly achieved through the usual equipment inspection stations. However, the usual inspection operations usually record the information of various disaster relief equipment and accessories in the form of a paper list, so it is not easy to implement disaster relief. The management of equipment and accessories is real-time, and it is not easy to track and obtain the efficiency of disaster relief equipment and accessories. In addition, because there is no systematic integration and management of firefighters' information, it is not easy to have a complete grasp of the firefighters' conditions.

However, among all kinds of disaster relief equipment, fire extinguishers are well known to the public. According to relevant national regulations, the mandatory scrapping life of dry powder fire extinguishers is 10 years, that is, the life of dry powder fire extinguishers cylinders is 10 years. However, the implementation rules of the Fire Protection Law clearly stipulate " According to the provisions of this law, the manager shall regularly inspect and repair fire safety equipment as follows: 1. Visual inspection: judge whether the fire safety equipment is damaged or not and whether its configuration is appropriate through appearance; 2. Performance inspection: judge whether the performance of the fire safety equipment is judged through operation Normal; 3. Comprehensive inspection: The function of fire safety equipment is judged through the overall operation or use of fire safety equipment. The inspections in the preceding paragraph are carried out every six months in Class A places specified by the standards for the installation of fire equipment in various places. Outside the premises, it will be implemented once a year."

Therefore, for fire extinguishers more than 3 years from the year of manufacture, appearance inspection and performance inspection must be performed according to more than 50% of the sampling number. After the inspection is qualified, the rest of the fire extinguishers can continue to be used. It is recommended to check the appearance and pressure every three months during the validity period of the fire extinguisher. , The air pressure part will cause the pressure gauge pointer to fall below the green range due to the fatigue of the pressure gauge, gaskets and hoses, or the fire extinguisher will cause the pressure gauge to fail due to the collision. When the above situation occurs, it should be returned to the original factory or Qualified units are checked and refilled.

Even if the fire extinguisher is inspected every three months in accordance with the regulations, if abnormal usage occurs between each inspection period, the fire extinguisher will be in a situation where the fire extinguisher does not meet the safety regulations during this empty window period, which will cause personnel There are doubts about life safety.

Therefore, after observing the above-mentioned deficiencies, the inventor of the present case came up with the present invention.

The main purpose of the present invention is to provide an intelligent fire-fighting equipment monitoring system, which is equipped with an equipment recording module in the pressure gauge. The equipment recording module has a wireless transmission function, and the equipment recording module detects liquid or gas in the fire-fighting equipment In addition, the equipment recording module detects the power value of the power supply component, and the equipment recording module sends the pressure value and power value to the cloud database, so as to prompt the user in real time, thereby ensuring the normal use of the fire fighting equipment. And reduce labor costs.

Another object of the present invention is to provide a monitoring method for an intelligent fire-fighting equipment monitoring system, which cyclically detects once every monitoring time through the monitoring module, and the data transmission module cyclically transmits the pressure value and the power every monitoring time The value is sent to the cloud database, and the pressure value and power value are displayed in real time through the management platform, so as to reduce the manpower to check the fire equipment through the paper list, thereby reducing the manpower cost.

In order to achieve the above objective, the present invention provides an intelligent fire-fighting equipment monitoring system, which includes: at least one fire-fighting equipment; an equipment recording module, the equipment recording module is assembled at one end of the fire-fighting equipment, the equipment recording module The assembly has an accommodating space; a circuit board, the circuit board is arranged in the accommodating space, and the circuit board is electrically connected to the fire fighting equipment, the circuit board includes a power supply module, the power supply The module provides power to the circuit board; a monitoring module, the monitoring module is arranged on the circuit board, the monitoring module is electrically connected to the power supply module, the monitoring module includes a pressure detection Unit and a power detection unit, the pressure detection unit detects a pressure data of the gas or liquid in the fire fighting equipment, the power detection unit detects a power data of the power supply module; a processing module Group, the processing module is arranged on the circuit board, and the processing module is electrically connected to the monitoring module, the processing module includes a storage unit, and the storage unit receives the pressure data and the power data; and A data transmission module, the data transmission module is arranged on the circuit board, the data transmission module is electrically connected to the processing module, the data transmission module transmits the pressure data and the power data to a monitoring data Library; wherein the monitoring module cyclically detects once every monitoring time, and the data transmission module cyclically transmits the pressure data and the power data to the monitoring database every monitoring time.

Preferably, the monitoring database stores the pressure data and the power data.

Preferably, the wireless network of the data transmission module and the monitoring database is selected from the group consisting of Bluetooth (Bluetooth), infrared (IR), third-generation mobile communication (3G), fourth-generation mobile communication (4G). ), wireless local area network (Wi-Fi), wireless local area network (WLAN), wireless communication (ZigBee), wireless communication (Z-wave), near field communication (NFC), fifth-generation mobile communication (5G), Long-distance low-power wireless communication (LoRa), energy recovery wireless communication (Enocean), IPv6-based low-speed wireless personal area network (6LowPan), radio frequency identification (RFID), short-range wireless communication (Wi-SUN), long-distance One of low-power wireless communication (FSK) and low-power wide-area communication (NB-IoT) wireless communication protocols.

Preferably, the monitoring database includes an arithmetic unit, the arithmetic unit receives the pressure data and the power data, and the arithmetic unit calculates a daily pressure data and a daily power data, and the pressure data, The power data, the daily pressure data, and the daily power data are displayed through a management platform of the monitoring database.

Preferably, it further includes a positioning module, the positioning module is arranged on the circuit board, the positioning module is electrically connected to the processing module, the positioning module generates a positioning information, and the The positioning information is sent to the monitoring database through the data transmission module.

Preferably, it further includes a temperature detection module, the temperature detection module is arranged on the circuit board, the temperature detection module is electrically connected to the processing module, and the temperature detection module is An environmental temperature data around the fire fighting equipment is detected, and the environmental temperature data is transmitted to the monitoring database through the data transmission module.

Preferably, it further comprises a data comparison module, the data comparison module is arranged on the circuit board, the data comparison module is electrically connected to the processing module, and the data comparison module is The pressure data, the power data, and the ambient temperature data are compared with a set value, respectively.

Preferably, the data comparison module further includes an alarm unit, and the alarm unit issues an alarm corresponding to the result of comparing the pressure data, the power data and the ambient temperature data with the set values.

To achieve the above objective, the present invention provides a monitoring method for an intelligent fire-fighting equipment monitoring system, which includes the following steps: the pressure detection unit of the monitoring module detects the gas or gas in the fire-fighting equipment every monitoring time The pressure data of the liquid; at the same time, the power detection unit of the monitoring module detects the power data of the power supply module every monitoring time; the storage unit of the processing module receives and stores the pressure data and The power data; the data transmission module transmits the pressure data and the power data to the monitoring database; the positioning module generates the positioning information, and the positioning information is transmitted to the monitoring data through the data transmission module Database; and the computing unit of the monitoring database calculates the daily pressure data and the daily power data, and the pressure data, the power data, the daily pressure data, and the daily power data are based on the monitoring data The management platform of the library is displayed.

Preferably, the temperature detection module detects the ambient temperature data around the fire-fighting equipment, and the ambient temperature data is transmitted to the monitoring database through the data transmission module; at this time, the data is compared The module performs a data comparison program. The data comparison program compares the pressure data, the power data, and the ambient temperature data with the set values; when the pressure data is less than the set value, the alarm unit sends out Alarm; when the power data is less than the set value, the alarm unit issues an alarm; and when the ambient temperature data is greater than the set value, the alarm unit issues an alarm.

The intelligent fire-fighting equipment monitoring system and monitoring method thereof provided by the present invention are mainly through the setting of the monitoring module, the pressure detecting unit and the power detecting unit of the monitoring module detect the liquid in the fire-fighting equipment Or the pressure data of the gas, and the power data of the power supply module detected, and the pressure data and the power data are transmitted to the monitoring database through the data transmission module in real time, so that the manager can monitor the factory in real time , The information of the fire-fighting equipment on each floor or outdoor of the office building, so as to achieve intelligent utility and provide safety in use, while achieving the purpose of real-time monitoring.

(First embodiment)

Hereinafter, referring to the drawings, the implementation form of the first embodiment of the intelligent fire-fighting equipment monitoring system of the present invention will be described.

Please refer to Figures 1 to 4. Figure 1 is a perspective view of the first embodiment of the present invention, Figure 2 is an exploded view of the first embodiment of the present invention, and Figure 3 is a schematic diagram of the system architecture of the first embodiment of the present invention. 4 is a schematic diagram showing the display of the management platform of the first embodiment of the present invention. The present invention discloses an intelligent fire-fighting equipment monitoring system 100, which includes:

At least one fire-fighting equipment 200. In this embodiment, as shown in FIG. 1, the fire-fighting equipment 200 is a fire extinguisher, but the present invention is not limited thereto. In another preferred embodiment, the fire-fighting equipment 200 is Fire hydrant, automatic sprinkler or different types of fire extinguishers.

An equipment recording module 10, the equipment recording module 10 is assembled with one end of the fire fighting equipment 200, and the equipment recording module 10 has an accommodating space 14. In this embodiment, as shown in FIG. 2, the device recording module 10 includes a cover 11, a pointer watch 12, and a housing 13. The housing 13 is recessed with the accommodating space 14, and the pointer watch 12 is arranged in the accommodating space 14. The pointer table 12 detects and displays the pressure value of the liquid or gas in the fire fighting equipment 200, and the cover 11 is assembled with the housing 13, so that the pointer table 12 is stably arranged in the accommodating space 14.

A circuit board 20, the circuit board 20 is arranged in the accommodating space 14, and the circuit board 20 is electrically connected to the fire fighting equipment 200, the circuit board 20 includes a power supply module 21, the power supply module The group 21 provides power to the circuit board 20. In this embodiment, as shown in FIG. 2, the circuit board 20 is electrically connected to the pointer watch 12, and the circuit board 20 and the pointer watch 12 are arranged in the accommodating space 14.

A monitoring module 30, the monitoring module 30 is arranged on the circuit board 20, the monitoring module 30 is electrically connected to the power supply module 21, the monitoring module 30 includes a pressure detection unit 31 and a Power detection unit 32, the pressure detection unit 31 detects a pressure data 311 of the gas or liquid in the fire fighting equipment 200, the power detection unit 32 detects a power data 321 of the power supply module 21 .

A processing module 40, the processing module 40 is arranged on the circuit board 20, and the processing module 40 is electrically connected to the monitoring module 30, the processing module 40 includes a storage unit 41, the storage unit 41 The pressure data 311 and the power data 321 are received.

A data transmission module 50, the data transmission module 50 is arranged on the circuit board 20, the data transmission module 50 is electrically connected to the processing module 40, the data transmission module 50 transmits the pressure data 311 and The power data 321 is sent to a monitoring database 60. In this embodiment, the wireless network of the data transmission module 50 and the monitoring database 60 is selected from Bluetooth, infrared (IR), third-generation mobile communications (3G), and fourth-generation mobile communications. (4G), wireless local area network (Wi-Fi), wireless local area network (WLAN), wireless communication (ZigBee), wireless communication (Z-wave), near field communication (NFC), fifth-generation mobile communication (5G) ), long-distance low-power wireless communication (LoRa), energy recovery wireless communication (Enocean), IPv6-based low-speed wireless personal area network (6LowPan), radio frequency identification (RFID), short-range wireless communication (Wi-SUN), One of the wireless communication protocols of long-distance low-power wireless communication (FSK) and low-power wide-area communication (NB-IoT).

It should be further explained that in this embodiment, the data transmission module 50 uses long-distance low-power wireless communication (Frequency Shift Keying, FSK). The following describes the advantages of FSK; one, wide coverage, Compared with traditional GSM, a base station can provide 10 times the area coverage, FSK can cover the range of 1km to 10km, and one base station in a small county can cover. At the same time, FSK has increased the gain of 20dB compared with LTE and GPRS base stations, and can cover underground garages, basements, underground pipelines and other places where signals are difficult to reach. In the past, it was impossible to have a signal to make calls in the basement, but FSK can still communicate; second , Can connect multiple at the same time, the frequency of 300MHz to 480MHz can provide 100,000 connections; third, low power consumption, use AA batteries to work for ten years, FSK reduces the power consumption during operation, and extends the battery life .

Specifically, as shown in FIG. 3, the monitoring database 60 stores the pressure data 311 and the power data 321, the monitoring module 30 cyclically detects every other monitoring time, and the data transmission module 50 every The pressure data 311 and the power data 321 are cyclically transmitted to the monitoring database 60 at intervals of the monitoring time. The monitoring time is between 1 minute and 30 minutes, but the present invention is not limited by this. The monitoring time is based on The needs of users have changed. 3 and 4, the monitoring database 60 includes an arithmetic unit 61, the arithmetic unit 61 receives the pressure data 311 and the power data 321, and the arithmetic unit 61 statistics a daily pressure data 312 and a Daily power data 322, and the pressure data 311, the power data 321, the daily pressure data 312, and the daily power data 322 are displayed through a management platform 62 of the monitoring database 60.

In order to further understand the structural features of the present invention, the technical means used and the expected effects, the use of the present invention is described. It is believed that a more in-depth and specific understanding of the present invention can be obtained from this, as follows:

Please continue to refer to FIGS. 1 to 4, the equipment recording module 10 is assembled with one end of the fire fighting equipment 200, and the pressure detecting unit 31 and the power detecting unit 32 of the monitoring module 30 are arranged every other The monitoring time cycle detects once, the pressure detection unit 31 detects the pressure data 311 of the gas or liquid in the fire fighting equipment 200, and the power detection unit 32 detects the power supply module 21 Power data 321; Then, the storage unit 41 of the processing module 40 receives and stores the pressure data 311 and the power data 321; then, the pressure data 311 and the power data 321 are transmitted to the data transmission module 50 Monitoring database 60; then, the monitoring database 60 receives the pressure data 311 and the power data 321, and the computing unit 61 of the monitoring database 60 calculates the daily pressure data 312 and the daily power data 322 .

Please continue to refer to FIG. 4, the pressure data 311, the power data 321, the daily pressure data 312 and the daily power data 322 are displayed through the management platform 62 of the monitoring database 60. The pressure data 311 of the fire fighting equipment 200 is 235 (PSI), and the power data 321 of the power supply module 21 is 5 (V), but the present invention is not limited by this. The pressure data 311 is in accordance with The capacity of the fire extinguisher, the material of the barrel or the material of liquid or gas are different from the pressure data 311, and the power value provided by the power supply module is different according to the needs of the user. In this embodiment, the fire fighting equipment 200 is plural, and the monitoring database 60 separately records a number data 33 and an expiration date data 34 of the fire fighting equipment, and the number data 33 and The validity period information 34 is displayed through the management platform 62.

In this way, it can be further understood from the above description that the present invention uses the setting of the monitoring module 30, and the pressure detecting unit 31 of the monitoring module 30 detects the pressure data of the liquid or gas in the fire fighting equipment 200 311, and the power detection unit 32 detects the power data 321 of the power supply module 21, and the pressure data 311 and the power data 321 are transmitted to the monitoring database 60 in real time through the data transmission module 50, by The management platform 62 of the monitoring database 60 displays the pressure data 311, the circuit data, the daily pressure data 312, and the daily power data 322, so that the manager can monitor each floor of the factory and office building in real time. Or the outdoor information of the fire fighting equipment 200 can achieve intelligent utility and provide safety in use, and achieve the purpose of real-time monitoring at the same time.

(Second embodiment)

Hereinafter, with reference to the drawings, the implementation form of the second embodiment of the intelligent fire-fighting equipment monitoring system of the present invention will be described.

Please refer to Figures 5 to 7. Figure 5 is a schematic diagram of the system architecture of the second embodiment of the present invention, Figure 6 is a schematic diagram of the use state of the second embodiment of the present invention, and Figure 7 is the use state of the second embodiment of the present invention Schematic. Compared with the first embodiment, the main structural difference of the second embodiment is that the intelligent fire-fighting equipment monitoring system 100 further includes a positioning module 70 which is arranged on the circuit board 20. The positioning module 70 is electrically connected to the processing module 40, the positioning module 70 generates a positioning information 71, and the positioning information 71 is transmitted to the monitoring database 60 through the data transmission module 50.

In this embodiment, as shown in FIG. 6, the fire fighting equipment 200 is plural, the monitoring database 60 receives the positioning information 71, and the positioning information 71 is displayed through the management platform 62. The management platform 62 The route map information is displayed and the location information 71 is displayed on the route map information at the same time, so that the administrator can know in real time whether the fire fighting equipment is located at the predetermined location, and suppose one of the fire fighting equipment is malfunctioning Or the expiration date has passed, the administrator can go to the location to repair or replace the fire fighting equipment 200 based on the positioning information 71, so as to increase the practicality of use and the convenience of management.

When the intelligent fire-fighting equipment monitoring system 100 is used on map information, as shown in FIG. 7, there are multiple fire-fighting equipment 200, and the monitoring database 60 receives the positioning information 71, and waits for the positioning information 71 to pass through the The management platform 62 shows that the management platform 62 displays the map information and the positioning information 71 is displayed on the map information at the same time. The manager clicks or touches one of the positioning information 71, and the management platform 62 is on the same The pressure data 311, the circuit data, the daily pressure data 312, and the daily power data 322 of the fire fighting equipment 200 corresponding to the location information 71 are displayed on the page.

Therefore, the second embodiment can not only achieve the effect of the first embodiment, but also provide a different structure. The second embodiment uses the positioning module 70 to generate the positioning information 71. The location information 71 is transmitted to the monitoring database 60 through the data transmission module 50, and the location information 71 is displayed through the management platform 62 of the monitoring database 60, so that the manager can track the location information 71 through the location information 71. The location of the fire-fighting equipment 200 can achieve practicality in use and convenience in management.

(The third embodiment)

Hereinafter, referring to the drawings, the implementation form of the third embodiment of the intelligent fire-fighting equipment monitoring system of the present invention will be described.

Please refer to Figures 8 and 9, and in conjunction with Figures 4 and 7. Figure 8 is a schematic diagram of the system architecture of the third embodiment of the present invention, and Figure 9 is a schematic diagram of the use state of the third embodiment of the present invention when a fire occurs . Compared with the first and second embodiments, the main structural difference of the third embodiment is that the intelligent fire-fighting equipment monitoring system 100 further includes a temperature detection module 80 and a data comparison module 90. The temperature detection module 80 is arranged on the circuit board 20, the temperature detection module 80 is electrically connected to the processing module 40, and the temperature detection module 80 detects the surrounding area of the fire fighting equipment 200 An ambient temperature data 81, and the ambient temperature data 81 is transmitted to the monitoring database 60 through the data transmission module 50. The data comparison module 90 is arranged on the circuit board 20, the data comparison module 90 is electrically connected to the processing module 40, and the data comparison module 90 compares the data with a set value. The pressure data 311, the power data 321, and the ambient temperature data 81. In addition, the data comparison module 90 further includes an alarm unit 91, and the alarm unit 91 issues an alarm corresponding to the result of comparing the pressure data 311, the power data 321 and the ambient temperature data 81 with the set values.

Specifically, the data comparison module 90 compares the pressure data 311, the power data 321, and the ambient temperature data 81 to the set values, respectively, and the pressure data 311 and the power data 321 are equal to the set values. When the setting value is set, the pressure detection unit 31 and the power detection unit 32 cyclically detect the pressure data 311 and the power data 321, and when the ambient temperature data 81 is equal to or less than the set value, the temperature detection mode Group 80 is to cyclically detect the ambient temperature data 81 around the fire fighting equipment 200. On the contrary, when one of the pressure data 311 and the power data 321 is greater than or less than the set value, the alarm unit 91 is activated and an alarm is issued , And when the ambient temperature data 81 is greater than the set value, the alarm unit 91 is activated and an alarm is issued.

Therefore, the third embodiment can not only achieve the effects of the first and second embodiments, but also provide different structures. The third embodiment uses the temperature detection module 80, the data comparison module 90, and The setting of the alarm unit 91, the temperature detection module 80 detects the ambient temperature data 81 around the fire fighting equipment 200, and the ambient temperature data 81 compares the set value through the data comparison module 90, and The alarm unit 91 generates an alarm corresponding to the set values compared to the results of the pressure data 311, the power data 321, and the ambient temperature data 81, so that the manager can instantly know the location of the fire and the relative The fire-fighting equipment 200, which is closer to the fire scene, further achieves rapid fire fighting and knows the direction of escape.

(Step flow of the monitoring method of the first embodiment)

Please refer to FIG. 10 in conjunction with FIG. 1 to FIG. 7. FIG. 10 is a flowchart of the monitoring method according to the first embodiment of the present invention. The present invention is based on the above-mentioned intelligent fire-fighting equipment monitoring system 100, and further provides a monitoring method of the intelligent fire-fighting equipment monitoring system 100, which includes the following steps:

Step S01a: The pressure detecting unit 31 of the monitoring module 30 detects the pressure data 311 of the gas or liquid in the fire fighting equipment 200 at intervals of the monitoring time.

Step S01b: At the same time, the power detection unit 32 of the monitoring module 30 detects the power data 321 of the power supply module 21 at intervals of the monitoring time.

Step S02: The storage unit 41 of the processing module 40 receives and stores the pressure data 311 and the power data 321.

Step S03: The data transmission module 50 transmits the pressure data 311 and the power data 321 to the monitoring database 60.

Step S04: The positioning module 70 generates the positioning information 71, and the positioning information 71 is transmitted to the monitoring database 60 through the data transmission module 50.

Step S05: The calculation unit 61 of the monitoring database 60 calculates the daily pressure data 312 and the daily power data 322, and the pressure data 311, the power data 321, the daily pressure data 312 and the daily The power data 322 is displayed through the management platform 62 of the monitoring database 60.

(Step flow of the monitoring method of the second embodiment)

Please refer to FIG. 11, which is a schematic diagram of the flow steps of the monitoring method according to the second embodiment of the present invention. Step S06: The temperature detection module 80 detects the ambient temperature data 81 around the fire fighting equipment 200, and the ambient temperature data 81 is transmitted to the monitoring database 60 through the data transmission module 50.

Step S07: At this time, the data comparison module 90 performs a comparison data procedure, which compares the pressure data 311, the power data 321 and the ambient temperature data 81 with the set values. The department includes the following steps:

Step S07a: When the pressure data 311 is less than the set value.

Step S071a: The alarm unit 91 issues an alarm.

Step S07b: When the power data 321 is less than the set value.

Step S071b: The alarm unit 91 issues an alarm.

Step S07c: when the ambient temperature data 81 is greater than the set value.

Step S071c: The alarm unit 91 issues an alarm.

Hereinafter, the characteristics of the present invention and the expected effects that can be achieved are stated as follows:

The intelligent fire-fighting equipment monitoring system and monitoring method of the present invention is achieved through the setting of the monitoring module 30. The pressure detecting unit 31 and the power detecting unit 32 of the monitoring module 30 detect the fire-fighting equipment 200 The pressure data 311 of the liquid or gas inside, and the power data 321 detecting the power supply module 21, and the pressure data 311 and the power data 321 are transmitted to the monitoring database in real time through the data transmission module 50 60, so that managers can monitor the information of the firefighting equipment 200 on each floor of the factory, office building or outdoor in real time, so as to achieve intelligent utility and provide safety in use, as well as to reduce labor costs and resources, and at the same time achieve The purpose of real-time monitoring.

Therefore, the present invention has the following implementation effects and technical effects:

First, the present invention uses the setting of the monitoring module 30 in conjunction with the data transmission module 50. The pressure detection unit 31 and the power detection unit 32 of the monitoring module 30 detect the inside of the fire fighting equipment 200 The pressure data 311 of the liquid or gas and the power data 321 of the power supply module 21 are detected. The pressure data 311 and the power data 321 are transmitted to the monitoring database 60 in real time through the data transmission module 50.

Second, the present invention uses the data transmission module 50 for long-distance low-power wireless communication (Frequency Shift Keying, FSK), so that the intelligent fire-fighting equipment monitoring system 100 achieves wide coverage, multiple simultaneous connections, and low power consumption. And the effect of not being blocked by obstacles.

Third, the present invention uses the configuration of the data transmission module 50, the monitoring database 60 and the positioning module 70, and the pressure data 311, the power data 321 and the positioning information 71 are transmitted in real time through the data transmission module 50 To the monitoring database 60, and the monitoring database 60 calculates and stores the daily pressure data 312 and the daily power data 322 in real time, and the management platform 62 displays the pressure data 311, the power data 321, and the daily power data in real time. The daily pressure data 312, the daily power data 322 and the positioning information 71, so that the manager can monitor and monitor the information of the fire fighting equipment 200 on each floor of the factory, office building or outdoor, so as to achieve the intelligent effect and improve the use On the safety, and reduce labor costs and resources.

Fourth, in the present invention, the temperature detection module 80, the data comparison module 90 and the alarm unit 91 are configured, and the temperature detection module 80 detects the ambient temperature data 81 around the fire fighting equipment 200 , And the ambient temperature data 81 compares the set values through the data comparison module 90, and the alarm unit 91 compares the pressure data 311, the power data 321, and the ambient temperature data 81 corresponding to the set values. The alarm is issued, so that the manager can instantly know the location of the fire, and know that the fire fighting equipment 200 is closer to the fire scene, so as to further achieve rapid fire extinguishing and know the escape direction.

In summary, the present invention has excellent progress among similar products. At the same time, we have checked the domestic and foreign technical data about this type of structure, and the same structure has not been found in the literature. Therefore, this At the time of the invention, the requirements for a patent for invention were already in place, and an application was filed in accordance with the law.

However, the above are only the preferred and feasible embodiments of the present invention. If there is no obvious repulsion between the embodiments, the features can be combined with each other to replace the application. Moreover, all equivalent structural changes made by applying the specification of the present invention and the scope of the patent application should be included in the scope of the patent of the present invention.

100: Intelligent fire protection equipment monitoring system 10: Equipment record module 11: Lid 12: pointer table 13: shell 14: accommodating space 20: circuit board 21: Power supply module 30: Monitoring module 31: Pressure detection unit 311: pressure data 312: Daily stress data 32: Battery detection unit 321: Electricity Data 322: Daily Electricity Data 33: serial number 34: Validity period information 40: Processing module 41: storage unit 50: data transmission module 60: Monitoring database 61: arithmetic unit 62: Management Platform 70: positioning module 71: Positioning information 80: Temperature detection module 81: Ambient temperature data 90: Data comparison module 91: Alarm unit 200: Fire fighting equipment

Fig. 1 is a perspective view of the first embodiment of the present invention. Figure 2 is an exploded view of the first embodiment of the present invention. FIG. 3 is a schematic diagram of the system architecture of the first embodiment of the present invention. Fig. 4 is a schematic diagram showing the management platform of the first embodiment of the present invention. FIG. 5 is a schematic diagram of the system architecture of the second embodiment of the present invention. Fig. 6 is a schematic diagram of the use state of the second embodiment of the present invention. Fig. 7 is a schematic diagram of the use state of the second embodiment of the present invention. FIG. 8 is a schematic diagram of the system architecture of the third embodiment of the present invention. Fig. 9 is a schematic diagram of the third embodiment of the present invention in the use state when a fire occurs. FIG. 10 is a schematic diagram of the flow steps of the monitoring method according to the first embodiment of the present invention. 11 is a schematic diagram of the flow steps of the monitoring method according to the second embodiment of the present invention.

100: Intelligent fire protection equipment monitoring system

11: Lid

12: pointer table

13: shell

14: accommodating space

20: circuit board

31: Pressure detection unit

32: Battery detection unit

40: Processing module

50: data transmission module

Claims (6)

An intelligent fire-fighting equipment monitoring system, which includes: at least one fire-fighting equipment; an equipment recording module, the equipment recording module sets one end of the fire-fighting equipment, the equipment recording module has an accommodating space; a circuit The circuit board is arranged in the accommodating space, and the circuit board is electrically connected to the fire fighting equipment, the circuit board includes a power supply module, and the power supply module provides power to the circuit board; A monitoring module, the monitoring module is arranged on the circuit board, the monitoring module is electrically connected to the power supply module, the monitoring module includes a pressure detection unit and a power detection unit, the pressure The detection unit detects a pressure data of the gas or liquid in the fire-fighting equipment, the power detection unit detects a power data of the power supply module; a processing module, the processing module is set in the Circuit board, and the processing module is electrically connected to the monitoring module, the processing module includes a storage unit, the storage unit receives the pressure data and the power data; and a data transmission module, the data transmission module The group is set on the circuit board, the data transmission module is electrically connected to the processing module, and the data transmission module transmits the pressure data and the power data to a monitoring database; wherein, the monitoring module every other A monitoring time cycle detects once, and the data transmission module cyclically transmits the pressure data and the power data to the monitoring database every the monitoring time; which also includes a temperature detection module, the temperature detection module The assembly is set on the circuit board, the temperature detection module is electrically connected to the processing module, the temperature detection module detects an ambient temperature data around the fire fighting equipment, and the ambient temperature data passes through the data The transmission module is transmitted to the monitoring database; which further includes a data comparison module, the data comparison module is arranged on the circuit board, the data comparison module is electrically connected to the processing module, the The data comparison module compares the pressure data, the power data, and the ambient temperature data with a set value respectively; wherein, the data comparison module further includes an alarm unit corresponding to the set values Compare the results of the pressure data, the power data and the ambient temperature data to issue an alarm; and Wherein, through the setting of the temperature detection module, the data comparison module, and the alarm unit, the temperature detection module detects the ambient temperature data around the fire-fighting equipment, and the ambient temperature data passes through the data The comparison module compares the setting value, and the alarm unit issues an alarm corresponding to the result of comparing the setting value to the pressure data, the power data and the ambient temperature data, so that the manager can instantly know the fire occurrence Location, and knowing that compared with the fire fighting equipment closer to the fire scene, it can further achieve rapid fire fighting and know the direction of escape. For example, the intelligent fire-fighting equipment monitoring system of claim 1, wherein the monitoring database stores the pressure data and the power data. For example, the intelligent fire-fighting equipment monitoring system of claim 1, wherein the wireless network of the data transmission module and the monitoring database is selected from Bluetooth (Bluetooth), infrared (IR), third-generation mobile communication (3G), Fourth-generation mobile communication (4G), wireless local area network (Wi-Fi), wireless local area network (WLAN), wireless communication (ZigBee), wireless communication (Z-wave), near field communication (NFC), fifth Mobile communication (5G), long-distance low-power wireless communication (LoRa), energy recovery wireless communication (Enocean), IPv6-based low-speed wireless personal area network (6LowPan), radio frequency identification (RFID), short-range wireless communication ( One of the wireless communication protocols of Wi-SUN), long-distance low-power wireless communication (FSK), and low-power wide-area communication (NB-IoT). For example, the intelligent fire-fighting equipment monitoring system of claim 1, wherein the monitoring database includes an arithmetic unit, the arithmetic unit receives the pressure data and the power data, and the arithmetic unit calculates a daily pressure data and a daily power Data, and the pressure data, the power data, the daily pressure data, and the daily power data are displayed through a management platform of the monitoring database. For example, the intelligent fire-fighting equipment monitoring system of claim 1, which further includes a positioning module, the positioning module is arranged on the circuit board, the positioning module is electrically connected to the processing module, and the positioning module generates A positioning information is output, and the positioning information is sent to the monitoring database through the data transmission module. A monitoring method using the intelligent fire-fighting equipment monitoring system according to claim 1, which includes the following steps: the pressure detection unit of the monitoring module detects the gas or liquid in the fire-fighting equipment at intervals of the monitoring time The pressure data; At the same time, the power detection unit of the monitoring module detects the power data of the power supply module every monitoring time; the storage unit of the processing module receives and stores the pressure data and the power data; the data The transmission module transmits the pressure data and the power data to the monitoring database; the positioning module generates the positioning information, and the positioning information is transmitted to the monitoring database through the data transmission module; and the monitoring data The calculation unit of the library calculates the daily pressure data and the daily power data, and the pressure data, the power data, the daily pressure data, and the daily power data are displayed through the management platform of the monitoring database ; Wherein, the temperature detection module detects the ambient temperature data around the fire-fighting equipment, and the ambient temperature data is transmitted to the monitoring database through the data transmission module; at this time, the data comparison module performs A data comparison program that compares the pressure data, the power data, and the ambient temperature data with the set values; when the pressure data is less than the set value, the alarm unit issues an alarm; when When the power data is less than the set value, the alarm unit issues an alarm; when the ambient temperature data is greater than the set value, the alarm unit issues an alarm; and wherein, through the temperature detection module, the data comparison model Group and the setting of the alarm unit, the temperature detection module detects the ambient temperature data around the fire-fighting equipment, and the ambient temperature data compares the set value through the data comparison module, and the alarm unit compares The set value should be compared with the result of the pressure data, the power data and the ambient temperature data to issue an alarm, so that the manager can instantly know the location of the fire, and know the fire fighting closer to the fire scene. Equipment to further achieve rapid fire fighting and know the direction of escape.

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