KR20230094899A - Fire warning system comprising early fire warning and evacuation for multi use facility - Google Patents

Abstract

The present invention relates to a fire alarm system for an early warning and evacuation system of a multi-dense facility fire, and more particularly, to a fire detector; a P-type receiver receiving a fire signal from the fire detector; A fire alarm terminal connected to the P-type receiver by wire and transmitting signal data transmitted from the P-type receiver to a management server through wireless communication; wherein the fire alarm terminal is connected to a plurality of P-type receivers A fire alarm system for fire early warning and evacuation systems in multi-dense facilities, characterized by collecting signal data from each P-type receiver, classifying the collected signal data into collected state and signal data for each individual receiver, and transmitting them to the management server provides

Description

Fire warning system comprising early fire warning and evacuation for multi use facility}

The present invention relates to a fire alarm system for an early warning and evacuation system of a multi-dense facility fire, and more particularly, includes a fire alarm terminal in a fire alarm system to relay fire information, and the fire alarm terminal is a fire information receiver (e.g. For example, by interlocking with P-type receivers) to receive signal data from a plurality of P-type receivers by wire and transmit it to the management server, a specific receiving module according to these protocols is installed from the P-type receiver that can have different communication protocols. Instead of wirelessly transmitting signal data directly to the managed management server, the fire alarm terminal collects the collected fire information data and receives them through the management server based on a single protocol to ensure the convenience of information transmission and reception.

In everyday life, the risk of fire always exists. It can be said that there is a lot of use of combustible building materials and the activation of the online market makes warehouses larger and more complex, so they are exposed to disaster environments that can lead to major accidents.

However, despite these risks, there are many cases in which the function of the fire extinguishing equipment is stopped due to fear of malfunction, and as a result, the fire extinguishing equipment does not operate even in the event of a fire, leading to a large fire.

For example, in the Dongtan Metapolis fire accident, 4 people died and 52 people were injured, but even in this case, fire extinguishing facilities did not work properly. In particular, out of a total of 2,345 days since opening in September 2010, earth alarms that sound sirens throughout the mall were 2,336 days (99.6%), fire shutters 2,179 days (92.9%), air supply fans 2,118 days (90.31%), and exhaust fans 2,033 days ( 86.69%) were all turned off, and it was investigated that they were briefly turned on only on special days such as fire inspection days. In addition, it is widespread in many buildings to stop the equipment itself to prevent malfunction.

Therefore, a system capable of checking the management status of firefighting facilities installed in a specific firefighting object is required, but such a system is currently absent, and it is only at the level of checking the operation only at the 6-monthly periodic operational function check. Therefore, it can be said that there is a need for a system that can check the state of firefighting facilities in the safety manager or the local fire station even in normal times. In particular, in the case of simply adding a sensor, it is analyzed that the addition of a sensor is undesirable because there is a problem in that the installation of the additional sensor is costly in terms of space and cost.

In addition, although disaster and fire-related IT-based technologies are currently being developed, they are applied only to large systems or expensive systems. There is no module that is shared and used for each P-type receiver. That is, communication protocols for each manufacturer of the P-type receiver are different, and it is impossible to obtain signal data from each P-type receiver through communication.

Republic of Korea Patent Publication No. 2004-0039513 (2004. 05. 12)

The present invention was made to solve the above-mentioned problems of the prior art, and the present invention collects signal data (fire signal, fire extinguishing equipment operation signal) of a P-type receiver as a wired contact signal in a module and transmits it wirelessly, Even if the communication protocols of the P-type receivers are different from each other, regardless of this, signal data can be obtained in a wired manner from the P-type receiver, and the building manager or the local fire department can check these signal data through an Ethernet network, etc. Its purpose is to provide a fire alarm system for early warning and evacuation systems of multi-dense facilities.

In order to achieve the above object, the present invention provides a fire detector; a P-type receiver receiving a fire signal from the fire detector; A fire alarm terminal connected to the P-type receiver by wire and transmitting signal data transmitted from the P-type receiver to a management server through wireless communication; wherein the fire alarm terminal is connected to a plurality of P-type receivers A fire alarm system for fire early warning and evacuation systems in multi-dense facilities, characterized by collecting signal data from each P-type receiver, classifying the collected signal data into collected state and signal data for each individual receiver, and transmitting them to the management server provides

Preferably, the P-type receivers differ from each other in some or all of the communication protocols they operate.

The fire alarm terminal may include an input module for receiving signal data including fire information from the P-type receiver; a conversion module for converting the signal data received from the input module into fire information or receiver status information; a calculation module for performing a signal data calculation process to determine a fire-related current state or firefighting facility operation state from the converted signal data; and a transmission module for converting the calculated signal data into a protocol for transmitting fire information and transmitting the converted signal data to the outside.

The fire alarm terminal preferably includes a port and a spare port for transmitting a PS/TS signal of a fire extinguishing facility, a switch status signal, and a fire signal.

Signal data transmission from the fire alarm terminal to the management server is preferably wireless transmission using a fixed IP.

The fire detector is a smoke detector, and as an independent alarm detector, it is preferable to transmit fire signal data to a fire alarm terminal in a wireless form by applying a firefighting wireless communication frequency of 447 MHz.

Preferably, the P-type detector receives operation signals including manual, automatic, and stop signals from fire extinguishing equipment and transmits them to display and fire alarm terminals.

In addition, the present invention is a method of operating the above-described system, which is performed by a fire alarm terminal, comprising the steps of obtaining signal data from a P-type receiver from a fire detector; converting the acquired signal data into fire information and receiver status information; deriving result data by calculating the converted signal data; and transmitting the resulting data to a management server in accordance with communication protocols.

According to the present invention as described above, the signal data (fire signal, fire extinguishing equipment operation signal) of the P-type receiver is collected by the module as a wired contact signal and transmitted wirelessly, so that even if the communication protocols of various P-type receivers are different from each other, this It enables signal data to be obtained from P-type receivers in a wired manner without a single fire alarm terminal and collectively receives signal data transmitted from multiple P-type receivers from building managers or local fire departments through an Ethernet network through a single fire alarm terminal. Therefore, the effect of prompt fire response can be expected.

1 is a schematic diagram showing a fire alarm system according to an embodiment of the present invention;
2 is a block diagram showing the internal structure of a fire alarm terminal;
It is a flowchart showing the driving flow of the fire alarm system of FIG. 3 .

Hereinafter, the present invention will be described in more detail based on preferred embodiments and accompanying drawings.

1 is a schematic diagram showing a fire alarm system according to an embodiment of the present invention, FIG. 2 is a block diagram showing the internal structure of a fire alarm terminal, and a flow chart showing a driving flow of the fire alarm system of FIG.

A fire detector is a device capable of automatically detecting the occurrence of a fire and sending an alarm to a receiver. At this time, there are five types of receivers: P-type, R-type, M-type, GP-type, and GR-type. Among them, the P-type receiver 100 transmits a signal transmitted from a detector or transmitter directly or through a repeater to a common signal. It is a receiver that receives and generates an alert. A common signal line of a certain monitoring area is connected from the detector and transmitter to the P-type receiver 100. If the number of monitoring areas is large, the number of signal lines is also required, but because the wiring is simple and inexpensive, it is widely used in small buildings. Normally, the P-type receiver 100 transmits a signal wirelessly, and the signal transmission protocol may vary according to specifications. At this time, when transmitting a signal including fire data from the P-type receiver 100 to the management server 300, the receiving module must be individually included to correspond to the signal transmission protocol corresponding to each P-type receiver 100, There is a problem that the scale of the device increases. Therefore, in the present invention, a fire alarm terminal 200 is configured between the P-type receiver 100 and the management server 300, and the fire alarm terminal 200 and the P-type receiver 100 are connected by wire, and the fire alarm It is characterized in that the terminal 200 transmits fire-related data as a signal to the management server 300 through wireless transmission. That is, the fire alarm terminal 200 can collectively receive fire-related signal data from various P-type receivers 100 and transmit the collected signal data to the management server 300 based on a fixed IP and a single protocol. The scale of equipment for data transmission can be reduced, the configuration can be simplified, and signal data transmission is very convenient.

The present invention is a fire detector; a P-type receiver 100 receiving a fire signal from the fire detector; A fire alarm terminal 200 connected to the P-type receiver 100 by wire and transmitting signal data transmitted from the P-type receiver 100 to the management server 300 through wireless communication; The fire alarm terminal 200 is connected to a plurality of P-type receivers 100, collects signal data from each P-type receiver 100, classifies the collected signal data into a collection state and signal data for each individual receiver, and manages the server. (300) to provide a fire alarm system for multi-dense facility fire early warning and evacuation systems.

Here, the fire detector is a smoke detector, and as an independent alarm detector, for example, it is preferable to transmit fire signal data to the fire alarm terminal 200 in a wireless form by applying a firefighting wireless communication frequency of 447 MHz. Here, the single alarm type detector is a sensor that independently detects and alarms a fire independently of a receiver, and when the system according to the present invention is installed, the single alarm type sensor can be additionally interlocked, adding compatibility. That is, in the present invention, the fire alarm terminal 200 transmits signal data to the fire alarm terminal through the communication module of the single type alarm detector by using an independent alarm detector separately from receiving signal data from the P-type receiver 100. can

Typically, the P-type receivers 100 differ from each other in some or all of the communication protocols they operate. When connected to a plurality of P-type receivers 100 using the same communication protocol, it will be possible to connect wirelessly with the fire alarm terminal 200, but this possibility is actually very small. That is, the plurality of P-type receivers 100 are more likely to be based on different protocols in wireless transmission. Therefore, the introduction of the present invention has advantages in these circumstances.

The fire alarm terminal 200 includes an input module 210 for receiving signal data including fire information from the P-type receiver 100; a conversion module 220 for converting the signal data received from the input module 210 into fire information or receiver state information; An arithmetic module 230 for performing a signal data calculation process in order to determine a fire-related current state or firefighting facility operation state from the converted signal data; and a transmission module 240 for converting the calculated signal data into a protocol for transmitting fire information and transmitting the converted signal data to the outside.

It is connected to the external P-type receiver 100 of the input module 210 by a wire to input signal data. It can also be connected to a single alarm type detector, but the single alarm type sensor is connected to the fire alarm terminal 200 wirelessly. That is, the fire alarm terminal 200 plays a bridge role in transmitting a signal to the management server 300 by being connected to the P-type receiver 100 by wire and by wireless to the independent alarm detector. When the signal data is converted into information by the conversion module 220, calculation is performed by the calculation module 230 to check the state, that is, as an example, whether the current firefighting equipment is operating normally or abnormally. . When the calculation is performed and the current fire state or the operation state of the firefighting equipment is confirmed, information is transmitted to the management server 300, and the activity of the fire alarm terminal 200 is performed in real time.

The fire alarm terminal 200 transmits a PS/TS signal of a fire extinguishing facility, a state signal such as operation, stop, or end of a switch included in the P-type receiver 100, and a fire signal including whether or not a fire has occurred. It may include ports and spare ports. Using this port, the corresponding signal is converted to the management server 300 and quickly transmitted. Prior to that, the P-type detector receives an operation signal including manual, automatic, and stop from the fire extinguishing equipment and transmits the signal to the display and fire alarm terminal 200.

Signal data transmission from the fire alarm terminal 200 to the management server 300 is preferably wireless transmission using a fixed IP. The use of static IP was implemented by setting detailed standards for the installation of integrated monitoring facilities as NFSC 607 (Fire Safety Standards for Underground Districts) became an administrative notice on July 16, 2020. Therefore, as an integrated fire monitoring facility, the effectiveness and scalability of the standard rules for integrated monitoring facilities can be achieved by using it as the basis (draft) of detailed standards related to integrated monitoring facilities such as fire stations and management offices that can include the management server 300, etc. can be obtained simultaneously.

In addition, the present invention is a method of operating the above-described system, which is performed by the fire alarm terminal 200, and the P-type receiver 100 obtains signal data from the fire detector (S410); converting the acquired signal data into fire information and receiver status information (S420); Calculating the converted signal data to derive resultant data (S430); And transmitting the resulting data to the management server 300 in accordance with the communication rules (S440); Provides a method of operating a fire alarm system for a multi-dense facility fire early warning and evacuation system, comprising .

This embodiment as described above is presented to explain the present invention in more detail, and it will be apparent that the claims are not limited to and interpreted by this embodiment.

Claims (8)

fire detector;
a P-type receiver receiving a fire signal from the fire detector;
a fire alarm terminal connected to the P-type receiver by wire and transmitting signal data transmitted from the P-type receiver to a management server through wireless communication;
Including,
The fire alarm terminal is connected to a plurality of P-type receivers, collects signal data from each P-type receiver, divides the collected signal data into a collection state and signal data for each individual receiver, and transmits the collected signal data to the management server. Fire alarm system for early warning and evacuation system of dense facility fire. According to claim 1,
The fire alarm system for a multi-dense facility fire early warning and evacuation system, characterized in that the communication protocols operated by the P-type receivers are different from each other in some or all. According to claim 1,
The fire alarm terminal,
an input module for receiving signal data including fire information from the P-type receiver;
a conversion module for converting the signal data received from the input module into fire information or receiver state information;
a calculation module for performing a signal data calculation process to determine a fire-related current state or firefighting facility operation state from the converted signal data;
a transmission module for converting the calculated signal data into a protocol for transmitting fire information and transmitting the converted signal data to the outside;
A fire alarm system for a multi-dense facility fire early warning and evacuation system comprising a. According to claim 3,
The fire alarm terminal,
A fire alarm system for a multi-dense facility fire early warning and evacuation system, characterized in that it includes a PS / TS signal of fire extinguishing equipment, a switch status signal, a port for transmitting a fire signal, and a spare port. According to claim 1,
The fire alarm system for a multi-dense facility fire early warning and evacuation system, characterized in that the signal data transmission from the fire alarm terminal to the management server is wireless transmission using a fixed IP. According to claim 1,
The fire detector is a smoke detector, a single alarm detector, and a multi-dense facility fire early warning and evacuation system characterized in that it transmits fire signal data to a fire alarm terminal in a wireless form by applying a 447 MHz firefighting wireless communication frequency. fire alarm system for According to claim 1,
The P-type detector,
A fire alarm system for a multi-dense facility fire early warning and evacuation system, characterized in that it receives operation signals including manual, automatic and stop from fire extinguishing equipment and transmits them to display and fire alarm terminals. As a method of operating the system of claim 1, it is performed by a fire alarm terminal,
obtaining signal data from the P-type receiver from the fire detector;
converting the acquired signal data into fire information and receiver status information;
deriving result data by calculating the converted signal data; and
Transmitting the resulting data to a management server based on communication rules;
A method of operating a fire alarm system for a multi-dense facility fire early warning and evacuation system comprising a.

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