KR20110108038A - Fire monitoring system for p-type control panel capable of on-site setup management - Google Patents

Abstract

A fire monitoring system capable of field setting management according to the present invention includes a P-type receiver and a field management terminal. The P-type receiver may include a mobile communication modem capable of transmitting and receiving a short message (SMS or MMS) through a mobile communication network, and a nonvolatile memory capable of storing user data. The field management terminal can receive user data by the engineer and can send and receive messages through the mobile communication network. The field management terminal may be operable to transmit user data input to the field management terminal to a mobile communication modem of the P-type receiver, and the P-type receiver may be operable to store the transmitted user data in a nonvolatile memory.

Description

FIRE MONITORING SYSTEM FOR P-TYPE CONTROL PANEL CAPABLE OF ON-SITE SETUP MANAGEMENT}

The present invention relates to a fire alarm equipment, and more particularly, to a fire alarm equipment implemented with a P-type receiver.

The National Fire Safety Standards (NFSC) is a set of regulations that set fire safety standards. Among them, the fire safety standards of the NFSC 203 automated fire detection system specify the conditions that must be provided by the building's automated fire detection system.

According to NFSC 203, a detector is a device that can automatically detect a fire and send an alarm to a receiver, and a sender is a device for notifying a person when a fire is directly detected. Among the various transmitters, the P-type Class 1 transmitter has a response lamp to confirm that a person has sent it, and has a telephone function to allow communication between the receiver and the transmitter. The P-type Class 2 transmitter has a push button but no telephone function. .

There are five types of receivers: P type, R type, M type, GP type and GR type, among which P type receiver receives signals from detectors or transmitters as a common signal either directly or through a repeater and alarms. Receiver. A common signal line from one surveillance zone is connected from the detector and transmitter to the P-type receiver. A large number of monitoring zones require a large number of signal lines, but they are widely used in small buildings because of their simple and inexpensive wiring.

Fire monitoring systems using P-type receivers can monitor P-type receivers 24 hours a day, or have a P-type receiver with automatic speed alarms to alert fire departments by telephone in the event of a fire.

The fire monitoring system, built as a P-type receiver, uses a 24V DC voltage signal and provides 24V DC power to each detector and transmitter. However, in reality, false alarms and malfunctions are frequently caused by deterioration of buildings or poor contact points, and the building managers often turn off the monitoring system and leave it unattended. In addition, the automatic warning is exempted from installation when the guard is resident in the building and the telephone is installed. If the automatic warning is installed, the fire alarm is automatically sent to the fire department through the automatic warning in case of false alarm or malfunction. This has led to increased distrust in fire alarms and disrupting firefighting.

For these reasons, although the installation of a P-type receiver is mandated by law for fire monitoring, in reality, the P-type receiver does not have a fire monitoring effect unlike the intention.

The problem to be solved by the present invention is to provide a fire monitoring system that can monitor the fire at a low cost by using a P-type receiver capable of performing a practical fire alarm, and can also manage the P-type receiver on-site. .

Fire monitoring system capable of field setting management according to an aspect of the present invention,

A P-type receiver including a mobile communication modem capable of transmitting and receiving a short message (SMS or MMS) through a mobile communication network, and a nonvolatile memory capable of storing user data; And

It is possible to receive the user data by the engineer, including a field management terminal that can send and receive messages through the mobile communication network,

The field management terminal is operable to transmit the user data input to the field management terminal to the mobile communication modem of the P-type receiver,

The P-type receiver may be operable to store the transmitted user data in the nonvolatile memory.

According to an embodiment, the user data transmitted from the field management terminal to the mobile communication modem of the P-type receiver may be transmitted in an SMS or MMS message.

According to one embodiment, the P-type receiver is

The site management terminal is transmitted by sending a short message for inquiring to an external control center server regarding whether the field management terminal having transmitted the user data has a legitimate authority and receiving a response to the query from the control center server. To authenticate,

After authentication passes, the user data may be stored in the nonvolatile memory.

According to an embodiment of the present disclosure, the field management terminal may be configured to transmit the user data to an external control center server so that the control center server updates the previously stored user data based on the transmitted user data. .

According to the present invention, it is possible to build a fire monitoring system that can give a practical fire alarm at a low cost using a P-type receiver, the user can visually check the fire alarm anytime, anywhere, the service provider is wired to the system The fire monitoring system can be set up on site as a management terminal without direct access.

1 is a conceptual diagram illustrating an exemplary fire monitoring system according to an embodiment of the present invention.
2 is a block diagram illustrating an exemplary P-type receiver according to an embodiment of the present invention.
3 is a block diagram illustrating a field management terminal for setting a P-type receiver in the field according to an embodiment of the present invention.
4 is a flowchart illustrating a site setting management procedure of a fire monitoring system based on SMS and MMS transmission according to an embodiment of the present invention.

With respect to the embodiments of the present invention disclosed in the text, specific structural to functional descriptions are merely illustrated for the purpose of describing embodiments of the present invention, embodiments of the present invention may be implemented in various forms and It should not be construed as limited to the embodiments described in.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment of the present invention. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 is a conceptual diagram illustrating an exemplary fire monitoring system according to an embodiment of the present invention.

Referring to FIG. 1, the fire monitoring system 10 includes a P-type receiver 12, a user terminal 13, a mobile communication network 14, a server 15 of a control center, and a terminal 16 for field management. It is configured by.

A plurality of detectors 111 and transmitters 112 are connected to the P-type receiver 12 via one common signal line 113 for each surveillance zone 11 in the building.

The P-type receiver 12 may identify the analog alarm signal received through the common signal line 113 and display the identified situation to the outside. The P-type receiver 12 may also generate a disaster prevention facility control signal corresponding to the identified situation. For example, when a fire occurs in the monitoring zone 11, an alarm signal indicating that a flame is detected in the detector 111 is applied to the P-type receiver 12 through the common signal line 113. The P-type receiver 12 is equipped with a plurality of LED indicator lamps, so that the monitoring zone 11 corresponding to the common signal line 113 to which an alarm signal is applied is displayed to the outside by the light emission of the LED indicator lamps. can do.

The P-type receiver 12 may generate, according to a predetermined form, a remote transmission message including the location information of the monitoring region 11 to which the detector 111 or the transmitter 112 which generated the alarm signal belongs.

The P-type receiver 12 may send the generated remote transmission message to the user terminal 13 or to the server 15 through the mobile communication network 14 using at least one protocol of SMS, MMS or email. .

For this purpose, the P-type receiver 12 may store the telephone number information of the user terminal 13, a message format for the remote transmission message, and a location table which is map information about the monitoring area 11. Such telephone number information, message format, and position table for the monitoring area 11 of the user terminal 13 are called user data.

At this time, the location table is registered with a hierarchical structure. For example, the name of the building complex in the first tier (xx university), the identification name of the building group in the second tier (engineering, law school, dormitory), and the identification name of the building in the third tier (study building, experimental building, auditorium, lecture hall) Etc.), each floor (1st, 2nd, 3rd floor) of the building in the 4th tier, sectors in each floor (east wing, west wing, lobby, machine room) in the 5th tier, The detectors and transmitters can be layered and registered in the order of the monitoring zones in which they are installed.

The P-type receiver 12 transmits a remote transmission message including the location information of the monitoring area 11 to which the detector 111 or the transmitter 112 which generated the alarm signal belongs to the location table stored in the P-type receiver 12. Can be generated according to a predetermined form by reference.

In this case, the location information included in the remote transmission message may combine data corresponding to the monitoring zone 11 where the fire occurred within each layer of the hierarchical structure by field, space, colon, semicolon, comma, period, slash ( It can be generated by separating fields with a delimiter such as /). For example, the location information of the monitoring zone 11 in which the fire occurred is located in the sixth field representing the monitoring zone from the first-level hierarchical field separated by the separator, respectively, "xx university / engineering college / first lecture building (E102 building)". / 2F / ipsilateral wing / 201 "in real time.

Context messages can likewise be generated through combinations.

The P-type receiver 12 may send the generated remote transmission message to the server 15 through at least one protocol of SMS and MMS.

The user terminal 13 may include a client capable of receiving SMS, MMS, or a client capable of receiving email.

On the other hand, the server 15 of the control center can be connected to the P-type receiver 12 via the mobile communication network (14). The server 15 may include a mobile modem (MODEM) capable of sending and receiving SMS or MMS messages via the mobile communication network 14 and making a TCP / IP connection. The server 15 may receive an authentication request for the field management terminal 16 from the P-type receiver 12 and notify the P-type receiver 12 of the authentication result.

The field management terminal 16 may be a PDA, a mobile phone, a smart phone, a portable computer including a mobile communication module, and the field management terminal 16, the P-type receiver 12, and the server 15 may be mobile communication. SMS, MMS messages can be sent to each other via the network 14.

Through this connection function, the field management terminal 16 may manage the P-type receiver 12. For example, the field management terminal 16 transmits the SMS and MMS message including the user data setting command and the user data to be set to the P-type receiver 12, and the P-type receiver 12 uses the field management for sending the message. The terminal 16 authenticates via the server 15.

The P-type receiver 12 may request the server 15 to authenticate the field management terminal 16. The authentication method may be a commonly used method. For example, the server 15 may be connected to the field management terminal 16 to confirm the ID and password of the field engineer, or may be authenticated using human body information such as a fingerprint of the field engineer. The SMS may be authenticated by sending a specific SMS authentication message to the field management terminal 16 and inputting a specific answer, or may be authenticated using a certificate stored in the field management terminal 16. The P-type receiver 12 may receive an appropriate response from the server 15 according to the result of such authentication.

When the authentication is completed, the P-type receiver 12 sets or updates user data managed by the P-type receiver 12 according to the transmitted user data. Depending on the embodiment, this authentication procedure may be omitted.

Specifically, in the present invention, the field engineer newly installs the P-type receiver 12 or performs maintenance work such as replacement of parts or firmware update, and the telephone number information of the user terminal 13 and the remote control to the P-type receiver 12. User data such as a message format for the transmission message and a position table as map information on the monitoring area 11 should be set. In this case, the field engineer may set user data using the field management terminal 16.

For this purpose, the field engineer drives the management application of the field management terminal 16. The management application performs input of user data, transmission of user data, transmission of test commands to the P-type receiver 12 and the like according to the operation of the field engineer.

2 is a block diagram illustrating an exemplary P-type receiver according to an embodiment of the present invention.

Referring to FIG. 2, the P-type receiver 12 includes a receiver 121, an alarm controller 122, and a data storage 123. The interface 124, the mobile communication modem 125, and the display unit 126 may be included.

Conventionally, the P-type receiver operated the display unit or the disaster prevention equipment through a simple connection of the input signal transmitted from the detector, but the P-type receiver 12, which is operated together with the control center server 15 of the present invention, samples the input signal, Alarm controller 122 implemented as a programmable processor, such as a CPU or SoC, to actively and intelligently perform an operation such as detecting an alarm signal, determining a false alarm, generating a remote transmission message, and generating a drive signal of an appropriate disaster prevention facility. Can be programmed. When the alarm controller 122 is implemented as an SoC, the data storage unit 123 may be implemented as a nonvolatile memory in the processor of the alarm controller 122 or may be implemented as a separate nonvolatile memory chip.

The receiving unit 121 receives the alarm signal generated by the detector 111 or the transmitter 112 in the monitoring area 11, the alarm control unit 122 identifies the received alarm signal, and the identified situation is The display unit 126 is displayed externally.

As described above, by law, the P-type receiver basically uses one signal line as the common signal line 113 for each individual monitoring zone 11, and the common signal line 113 of any one monitoring zone 11 is a detector ( 111 and transmitter 112 to P-type receiver 12. Therefore, it is possible to identify the situation in which monitoring zone 11 a fire has occurred, according to which common signal line 113 an alarm signal is received. On the front of the P-type receiver 12, display units 126 for indicating whether or not a fire has occurred in each monitoring zone 11 are provided.

Although not shown, in addition, the alarm control unit 122 of the P-type receiver 12 may generate a disaster prevention facility control signal corresponding to the identified situation. For example, if it is identified that a fire has occurred in a surveillance zone 11, the P-type receiver 12 may be a sprinkler, fire shutter, smoke control device, emergency light installed in the surveillance zone 11 or an adjacent surveillance zone 11. It is possible to generate a control signal for each disaster prevention facility so as to operate the induction lamp, and to emit a warning broadcast. The generated control signal may be output to each disaster prevention facility by an output unit configured separately.

The alarm controller 122 may include a data storage unit 123 in a built-in nonvolatile memory. The data storage unit 123 may include an identification number of the mobile communication modem 125 and an installation location of the P-type receiver 12. You can store user data and firmware, such as a location table, a status message form, and a hierarchical structure of map information, including address, building name, building name, floor, and fire monitoring zone settings.

The alarm control unit 122 refers to the remote transmission message including the location information of the monitoring region 11 to which the detector 111 or the transmitter 112 which generated the alarm signal belongs, in advance, with reference to the data storage unit 123. Create according to a fixed format.

The remote transmission message may be completed by inputting information included in the data storage unit 123 into a predetermined form. The format of the remote transmission message includes fields separated by delimiters such as commas, colons, semicolons, spaces, and the like. For example, the remote transmission message may be prepared in the order of the location information field, the status message field, and additional fields of the building and the monitoring area where the fire alarm occurred.

The location information included in the remote transmission message may be generated by combining data corresponding to the monitoring zone 11 where the fire occurred in each layer of the hierarchical structure and distinguishing fields by a separator. For example, the location information of the fire zone 11 in which the fire occurred is located in the top field or the lowest field representing the zone of monitoring, respectively, "xx university / engineering / 1st lecture building (E102 building) / 2nd floor / east wing / 201 Fields can be generated in real time by separating them with separators.

Context messages can likewise be generated through combinations. For example, the status message may be configured by combining examples of "sensor", "sender, fire", "gas", "electricity", and "sensing circuit test" stored in the data storage unit 123 in advance. Can be.

Finally, the additional field may include, for example, authentication data.

The identification number of the mobile communication modem 125 and the wireless modem identification number of the transmission target server 15 may be a mobile phone number of the mobile communication company to enable text transmission and reception.

The alarm controller 122 generates and outputs a transmission command through the interface 124 according to a destination of the completed remote transmission message and according to a transmission protocol. For example, if the destination of the remote transmission message is the wireless modem of the server 15 and the transmission protocol is SMS, the transmission command may be generated as follows.

at * skt * moreq = 0, [destination number], [destination number], [TI], <remote transmission message>

Here, at is a command for starting a CDMA modem of the mobile communication modem 125, and skt is a syntax for specifying a mobile communication company. Moreq is a command to send an SMS message to the CDMA modem of the mobile communication modem 125, where 0 is the sequence number of the message. The reception number includes the mobile communication identification numbers of the wireless modem of the server 15, and the reply number includes the mobile communication identification number assigned to the mobile modem 125. TI is a command to send a message immediately.

Meanwhile, the alarm controller 122 receives a control message including a user data setting command and a data message including user data to be set in the form of SMS and MMS messages from the field management terminal 16 through the mobile communication modem 125. Can be.

The alarm controller 122 may perform a user data setting operation according to a user data setting command in the control message. The alarm control unit 122 queries the server 15 via SMS and MMS messages to determine whether the field management terminal 16, which has sent such a control message, is a legitimate device prior to setting user data. Can be received from the server 15 through. After the authentication is performed, the alarm controller 122 may update the corresponding user data in the data storage unit 123 with the user data included in the data message.

The interface 124 may be a serial input / output port such as RS-232 or USB to enable communication between the alarm controller 122 and other components, for example, the mobile communication modem 125.

The interface 124 transmits the remote transmission message to the connected mobile communication modem 125, and the mobile communication modem 125 transmits the remote transmission message to the outside through at least one protocol of SMS and MMS. In addition, the interface 124 may receive a control message, a data message, or a data packet from the mobile communication modem 125 and transmit the received control message to the alarm controller 122.

According to an exemplary embodiment, the alarm controller 122 may be directly connected to the mobile communication modem 125 and transmit a transmission command without using a separate interface 124.

The mobile communication modem 125 may be, for example, a CDMA modem or a WCDMA modem. CDMA modems or WCDMA modems are wireless modems capable of transmitting character data over a CDMA or WCDMA mobile communication channel.

The mobile communication modem 125 may transmit SMS and MMS messages through the mobile communication network 14 to a designated reception number according to a transmission command received from the alarm controller 122 through the interface 124.

The display unit 126 includes output devices such as a plurality of indicators and a speaker mounted on the front of the P-type receiver, and under the control of the alarm control unit 122, a test state, a fire alarm state of each monitoring zone, and a power supply state Etc. can be displayed externally.

3 is a block diagram illustrating a field management terminal for remotely managing a P-type receiver according to an embodiment of the present invention.

3, the field management terminal 16 may be described based on a conventional mobile communication terminal or a PDA. The field management terminal 16 includes a terminal controller 161, a storage 162, a memory 163, a display 164, and an operation unit 165. The management application 166 is stored in the storage 162. The field management terminal 16 may load and execute the management application 166 stored in the storage 162 into the memory 163 to perform user data or firmware update for the P-type receiver 12.

When the management application 166 is driven in the terminal control unit 161, the terminal control unit 161 authenticates the field management terminal 16 to the server 15, and stores the data of the P-type receiver 12 from the field engineer User data such as a telephone number of the user's terminal 13 to be stored in the unit 123 and map information regarding the monitoring area 11 are received and transmitted to the server 15.

Next, a procedure for setting up the P-type receiver 12 by the field engineer using the field management terminal 16 will be described.

When the P-type receiver 12 is first installed in a building, the firmware for driving the alarm control unit 122 is set to a factory setting, and the user data is blank. At this point, the mobile communication modem 125 of the P-type receiver 12 has been opened so that the mobile communication network 14 can be used by the mobile communication company. It is recommended that various user data specific to the installation site be set up by the field engineer after installation.

The management application 166 receives user data to be set in the P-type receiver 12 from the field engineer. The field engineer can specify the information that can specify the P-type receiver 12, the telephone number of the user terminal 13 to receive the remote transmission message of the P-type receiver 12, and the monitoring area 11 of the P-type receiver 12. Map information related to may be input. In this case, the map information may be input in the form of a data file prepared in a predetermined table format by using a PC or the like instead of directly inputting it in the field.

When the input is completed, the management application 166 loads the input user data and the user data setting command in the SMS and MMS messages from the field management terminal 16 to the P-type receiver 12 via the mobile communication network 14. Send it.

Meanwhile, the management application 166 may transmit the input user data to the server 15 through the mobile communication network 14. The server 15 maintains the user information DB and the location table for the P-type receiver 12, respectively, and adds the transmitted information to the user data DB and the location table for the corresponding P-type receiver 12, respectively. Update

The procedure for setting user data by the P-type receiver 12 is as described above with respect to the P-type receiver 12.

When the transmission and update is completed, the field management terminal 16 receives the work completion message from the P-type receiver 12 in the form of SMS, MMS message, and displays the work completion message to the field engineer. The management application 166 may send an SMS or MMS message carrying a test command to cause the P-type receiver 12 to send a test message to the telephone number of the user terminal 13 which has been set up.

The field management terminal 16 enables the field engineer to keep the user data of the P-type receiver 12 up to date while installing, maintaining, modifying, and repairing the P-type receiver 12.

4 is a flowchart illustrating a site setting management procedure of a fire monitoring system based on SMS and MMS transmission according to an embodiment of the present invention.

Referring to FIG. 4, first, the field management terminal 16 receives user data regarding the P-type receiver 12 according to an operation of a field engineer (S41), and transmits user data and a user data setting command to a mobile communication network ( 14) it is transmitted to the P-type receiver 12 in the form of an SMS or MMS message (S42).

The P-type receiver 12 requests authentication from the server 15 in order to confirm whether the field management terminal 16 which has transmitted the SMS and MMS message is a terminal having a legitimate authority (S43). In some embodiments, this authentication procedure may be omitted. The authentication request can be made via SMS or MMS message.

The server 15 confirms that the field management terminal 16 is currently performing a legitimate work in a legal place, and transmits the authentication result to the P-type receiver 12 via SMS and MMS message (S44).

When the authentication is made, the P-type receiver 12 extracts user data from the received SMS or MMS message according to the user data setting command and stores the user data in the data storage unit 123 (S45).

When the setting of the user data is completed, the P-type receiver 12 transmits a work completion message to the field management terminal 16 as an SMS or MMS message (S46).

On the other hand, the field management terminal 16 may transmit the input user data to the server 15 (S47). The server 15 may update its own user data DB and location table based on the received user data (S48).

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications will fall within the scope of the invention.

11 watched areas
12 P-type Receiver 122 Alarm Control
125 mobile modem
13 User Terminal
14 Mobile Network
15 control center server
16 Field management terminal

Claims (4)

A P-type receiver including a mobile communication modem capable of transmitting and receiving a short message (SMS or MMS) through a mobile communication network, and a nonvolatile memory capable of storing user data; And
It is possible to receive the user data by the engineer, including a field management terminal that can send and receive messages through the mobile communication network,
The field management terminal is operable to transmit the user data input to the field management terminal to the mobile modem of the P-type receiver,
And the P-type receiver is operable to store the transmitted user data in the nonvolatile memory. The fire monitoring system of claim 1, wherein the user data transmitted from the field management terminal to the mobile communication modem of the P-type receiver is transmitted in an SMS or MMS message. The method of claim 1, wherein the P-type receiver
The site management terminal is transmitted by sending a short message for inquiring to an external control center server regarding whether the field management terminal having transmitted the user data has a legitimate authority and receiving a response to the query from the control center server. To authenticate,
And to store the user data in the non-volatile memory after authentication passes. The method of claim 1, wherein the field management terminal is characterized in that for transmitting the user data to an external control center server to operate the control center server to update the previously stored user data based on the transmitted user data. Fire monitoring system with on-site setting management.

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