KR101311950B1 - Fire detecing and alarm system - Google Patents

Abstract

PURPOSE: A fire sensing and warning system having a bidirectional communication loop is provided to improve reliability of fire sensing and warning actions. CONSTITUTION: A fire sensing and warning system having a bidirectional communication loop is formed with an interface unit as the center (30). The interface unit is connected to a main control panel (40), a relay unit, a power source, all kinds of the sensors, and switches. All kinds of the sensor, the switches, and alarms are connected to one communication loop. The communication loop provides a connection terminal in the interface unit and is expanded to several. The interface unit bonds both ends of lines which communicate with the main control panel and form the communication loop and outputs a signal for controlling the power source and the sensors for the communication loop. The interface unit receives information which is outputted from the sensor and transmits it to the main control panel. The main control panel is connected to the interface unit through a control communication terminal and senses a fire generation situation by receiving all kind of signals which is transmitted from the interface unit. The main control panel warns the fire generation situation and executes a firefighting action by transmitting all kinds of signals for controlling an action of multiple relays to the interface unit. [Reference numerals] (30) Interface unit; (40) Expand up to 4; (AA) Repeater panel; (BB) Main control panel; (CC) Two DOORHOLDERs; (DD) Eight RELAYs; (EE) Relay unit; (FF) Expand up to 4 (total 128 RELAYs except INTERFACE); (GG) Loop base; (HH) Loop card 1; (II) Loop card 2; (JJ) Loop card 3; (KK) Loop card 4; (LL) Expand up to 3 (total 12 LOOPs 1536 DEVICEs); (MM) 126 DEVICEs per a LOOP

Description

Fire detection alarm system with two-way communication loop {FIRE DETECING AND ALARM SYSTEM}

The present invention relates to a fire detection alarm system having a bidirectional communication loop, and more particularly, to a fire detection alarm system having a bidirectional communication loop having a loop configured by combining a plurality of fire detectors in parallel. The present invention relates to a fire detection alarm system having a two-way communication loop implemented to execute a fire detection function even if a wire break occurs in the middle.

As a fire detection and alarm countermeasure for large spaces, such as inside and outside of ships, plants or buildings, smoke detectors to detect smoke generation, temperature detectors to detect ambient temperature, flame detectors to detect flame occurrence, etc. The system has been configured and applied to arrange a large number and to detect the occurrence of a fire according to the operation of each detector.

Such a system includes a communication loop structure in which a (+) line to which the (+) terminal of each detector is connected and a (-) line to which the (-) terminal of each detector are connected in parallel, and one end of the communication loop structure. And an interface unit to which the other end is connected. Each detector is connected in parallel to the communication loop structure by simultaneously connecting to the positive and negative lines of the communication loop structure.

When the interface unit applies a voltage to operate each detector through the positive line of one end of the communication loop structure, each detector operates in order to change the current in response to its detection result. On the other end of the communication loop structure, the change of current in the (+) line or the (-) line can be recorded to detect the occurrence of a fire.

However, in such a structure, when a fire breaks out and a part of the communication loop is cut off, the operation of all the detectors connected to the communication loop structure is paralyzed.

The present invention is to solve the above problems, in the fire detection alarm system having a two-way communication loop by continuing the operation of the detector even if the communication loop is connected to a plurality of detectors, thereby improving the reliability of the fire detection and alarm operation Let's do it.

A fire detection alarm system having a bidirectional communication loop according to the present invention for achieving the above object is arranged in parallel with the (+) line for transmitting a predetermined operating voltage and the digital call signal and the (+) line. A communication loop including a (-) line and being a reference voltage of the (+) line; A sensor connected to the (+) line and the (-) line of the communication loop and driven by the operating voltage of the (+) line to sense a fire occurrence condition from the surrounding environment and generate a measurement value; And analyzing the digital call signal of the (+) line to generate a current signal representing the measured value by varying the current flowing from the (+) line to the (-) line at the time it is called. Including a fire detector; A control communication terminal for receiving the digital call signal, a power supply terminal for receiving the operating voltage, a loop A terminal connected to one end of the (+) line and the (-) line of the communication loop, A loop B terminal to which the other end of the (+) line and the (-) line of the communication loop are connected, the operating voltage and the digital call signal are output from each of the (+) lines, and from each of the (-) lines An interface unit including an MCU which, upon receiving the current signal, converts the received current signal into the measured value of a corresponding fire detector and outputs it through the control communication terminal; Connected to the interface unit via the control communication terminal, providing the digital call signal to the interface unit for calling the fire detector, receiving the measured value from the called fire detector and inputting in advance It includes a main control panel that performs programmatic processing.

In addition, the interface unit comprises a positive circuit of the (+) terminal of the loop A terminal and the (+) terminal of the loop B terminal in separate circuits, and simultaneously provides the operating voltage and the digital call signal at each (+) terminal. Outputs and detects the current signal separately at each of the (-) terminal of the loop A terminal and the (-) terminal of the loop B terminal, and the (-) terminal of the loop A terminal and the ( -) It is characterized by combining the respective current signals detected at the terminal.

The digital call signal may be modulated using the operating voltage as a carrier.

In addition, the fire detector, smoke detector for detecting the generation of smoke, temperature detector for detecting the ambient temperature, flame detector for detecting the occurrence of flame, emergency manual push switch that can be manually operated in the event of an emergency, set And at least one of timers for timing time.

In addition, the fire detector,

And a filter for separating the digital call signal from the operating voltage of the communication loop.

According to the fire detection alarm system having a two-way communication loop according to the present invention having the above configuration, by continuing the operation of the detector even if a part of the communication loop is connected to a plurality of detectors, it is possible to improve the reliability of the fire detection and alarm operation It becomes possible.

1 is a view showing the overall structure of a fire detection alarm system having a two-way communication loop according to the present invention.
2 is a block diagram of a fire detection alarm system having a bidirectional communication loop in accordance with the present invention.
3 is a diagram for explaining the operation of a feature portion of a fire detection alarm system having a bidirectional communication loop according to the present invention.
4 is a diagram illustrating an operating voltage, a digital call signal, and a current signal.
5 is a block diagram showing the configuration of a fire detector.
FIG. 6 is a diagram for describing an operation of outputting an operating voltage and a digital call signal at each (+) terminal and detecting the same at each (−) terminal.
FIG. 7 is a view for explaining the operation of each terminal in the case of outputting a digital call signal for selecting the operating voltage and the fire detector ② from the positive terminals on both sides of the loop as shown in FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration and operation of the fire detection alarm system having a bidirectional communication loop according to the present invention.

1 is a view showing the overall structure of a fire detection alarm system having a two-way communication loop according to the present invention. 2 is a block diagram showing the configuration of FIG. 1. (In FIG. 2, the loop base unit should be understood as a configuration included in the interface unit.)

Referring to the drawings, a fire detection alarm system having a bidirectional communication loop according to the present invention is made around the interface unit 30, and the interface unit 30 includes a main control panel 40, a relay unit, and a power supply. It can be seen that (P), various sensors 20 and switches, alarms, external network (e.g., the Internet) or computer can be connected.

Various detectors 20, switches and alarms are connected to one communication loop 10. That is, the positive terminal and the negative terminal of the devices comprising at least two parallel lines 11 and 12 connected at both ends to the interface unit 30, each of which includes a detector 20. By connecting each device in parallel.

Devices that may be connected to the communication loop 10 are, for example, smoke detectors for detecting the occurrence of smoke, temperature detectors for detecting the ambient temperature, flame detectors for detecting the occurrence of flame, and manual operation in the event of an emergency. Includes emergency manual push switch, timer to set time, alarm and additional I / O unit.

The communication loop 10 can be extended to a plurality if the interface unit 30 can provide a connection terminal (for example, a loop card). In addition, devices that may be connected to the communication loop 10 may be added to the extent to distinguish each device within the communication loop. For example, if the devices are distinguished by 7-bit signals in the communication loop 10, 127 devices may be connected.

The interface unit 30 communicates with the main control panel 40, and both ends of the lines 11 and 12 constituting the communication loop 10 are coupled, and the power supply P and the communication loop 10 are connected to each other. A signal for controlling the detector 20 is output. In addition, the sensor 20 receives information (current signal) output from each detector 20 and transmits the information to the main control panel 40.

The interface unit 30 may be provided with a plurality of loop base units (LOOPBASE UNIT) in which a plurality of loop cards (LOOPCARDs) constituting the communication loop 10 are arranged, thereby providing a very large number of communication loops. And it is possible to individually control the detectors connected thereto.

And, the relay unit (RELAY UNIT) is connected to the interface unit 30, when receiving a signal to control the operation of the relay unit from the main control panel 40, and controls the corresponding relay.

The main control panel 40 is connected through the interface unit 30 and the control communication terminal 35 and receives various signals (for example, measured values from a fire detector) transmitted from the interface unit 30. By detecting a fire occurrence situation and transmitting various signals for controlling the operation of a plurality of relays to the interface unit 30, it is possible to alert the fire occurrence situation and execute a fire extinguishing operation.

3 is a diagram for explaining the operation of a feature portion of a fire detection alarm system having a bidirectional communication loop according to the present invention. The fire detection alarm system having a bidirectional communication loop according to the present invention has improved the manner of controlling each communication loop connected to the interface unit, so as to achieve the above object. In the drawing, the configuration of the loop card is omitted, and the interface unit is briefly illustrated as forming only one communication loop.

First, the communication loop 10 includes a positive line 11 for transmitting an operating voltage provided from the interface unit 30 and a digital call signal transmitted from the main control panel 40, and the positive line. It comprises a negative line (12) arranged in parallel and being the reference voltage of the positive line.

Various fire detectors 20 are connected to the positive and negative lines of the communication loop 10. The fire detector 20 is driven by the operating voltage of the (+) line 11 to generate a measurement value by detecting a specific condition (for example, a condition for detecting a fire occurrence) from the surrounding environment. In addition, the current flowing from the (+) line to the (-) line through the fire detector in order to receive the digital call signal of the (+) line 11 and represent the measured value generated at the time when it is called as digital information. To generate a current signal. The generated current signal can be detected at each negative terminal of the interface unit.

That is, referring to FIG. 4 describing the operating voltage, the digital call signal, and the current signal, each fire detector 20 is applied to a voltage (operating voltage) for operating each fire detector 20 connected to the communication loop 10. You can see the modulated voltage waveform that contains the call information for selecting), and also receives the voltage waveform and inputs the measured value at the time when each detector 20 operates and is called. You can check the current waveform being converted into a signal and outputting.

The interface unit 30 includes a control communication terminal 35 for receiving a digital call signal from the main control panel 40, a power supply terminal 36 for receiving an operating voltage from an external power supply P, and a communication loop ( 10, a loop A terminal 31 connected to one end of the (+) line 11 and the (-) line 12 of the line 10, and the (+) line 11 and the (-) line 12 of the communication loop. And the other ends of the loops) have loop B terminals 32 connected to each other.

Since the communication loop 10 is configured with the (+) line 11 and the (-) line 12 in parallel, the loop A terminal 31 connects the (+) terminal 311 and the (-) terminal 312. Similarly, the loop B terminal 32 also has a positive terminal 321 and a negative terminal 322.

At this time, the (+) terminal 311 of the loop A terminal 31 and the (+) terminal 321 of the loop B terminal 32 are each composed of separate circuits, but simultaneously output the same operating voltage and digital call signal. It is configured to. In this way, when an abnormal state occurs in which the circuit of one (+) terminal is shorted or disconnected, stable operation of the system can be enhanced by stopping the circuit of the terminal.

On the other hand, the (-) terminal 311 of the loop A terminal 31 and the (-) terminal 322 of the loop B terminal 32 are configured independently of each other, and in the interface unit 30, each (-) terminal is separated from each other. Measure each input current signal. The measured current signals can be combined with each other. The combination may for example be an OR operation.

On the other hand, since the current signal detected at the (-) terminal of the loop A terminal 31 and the current signal detected at each of the (-) terminal of the loop B terminal 32 will contain the same information, there is no crosstalk of information. . Rather, the fire detector 20 is called using one (+) terminal 311 or 321 and configured to sense current signals individually at the same time on both (-) terminals of the communication loop 10, thereby communicating. Even if a disconnection occurs in any part of the loop 10, at least one negative terminal can detect a current signal (to be described later).

As a result, the interface unit 30 simultaneously transmits the operating voltage and the digital call signal to each of the positive terminals 311 and 321 of the loop A terminal 31 and the loop B terminal 32 so that any of the communication loops 10 Even if a break occurs in the part, it is possible to transmit the operating voltage and the digital call signal for all fire detectors.

The interface unit 30 converts the current signal output by the fire detector 20 into a measured value of the corresponding fire detector 20 and outputs it to the main control panel 40 through the control communication terminal 35. .

This operation of the interface unit is controlled by the MCU 38.

The main control panel 40 outputs a digital call signal for sequentially selecting (calling) a plurality of fire detectors 20 connected to the communication loop 10 of the interface unit 30 one by one. In addition, it receives the measurement value generated in the called fire detector 20 and transmitted through the interface unit 30 to perform a process according to a pre-input program.

That is, if the measured value indicates the occurrence of flame, the main control panel 40 may display that a fire has occurred at the position of the corresponding fire detector 20. In addition, it is also possible to output a signal for driving a relay connected to the fire extinguishing equipment of the location.

5 is a block diagram schematically showing the configuration of a fire detector. Referring to the drawings, the fire detector 20 is connected to each of the (+) line and the (-) line connecting the loop A terminal 31 and the loop B terminal 32 through the communication terminal 26. have. The power supply unit 21 receives the operating voltage from the (+) line and the (-) line to supply power used in the fire detector 20.

The communication unit 22 is connected to the (+) line and the (-) line, and can extract only the digital call signal by removing the operating voltage through the filter 23. In addition, the communication unit 22 serves to output a current signal output from the fire detector 20 through a communication loop.

The sensor 24 generates measurements for any one or a plurality of parameters related to the occurrence of a fire from the environment.

The CPU 25 controls the operation of each part of the fire detector 20. That is, by supplying the operating voltage from the power supply to the sensor 24 so that the detection function can be executed, converts the measured value measured by the sensor 24 into a digital signal, and combines the digital signal to the current flowing through the fire detector module Rate, and outputs this current signal through the communication unit 22.

In this way, the communication unit 22 is configured to separate the digital call signal carried on the operating voltage applied to the communication loop 10 through the filter 23, thereby the fire detector 20 in the main control panel 40 There is no need to configure a separate communication line to reach the power line can be used as a communication line.

FIG. 6 is a diagram for describing an operation of outputting an operating voltage and a digital call signal at each (+) terminal of the loop A terminal and the loop B terminal, and detecting the same at each (−) terminal. In the present invention, as shown in the drawing, the (+) terminal of the loop A terminal 31 and the (+) terminal of the loop B terminal 32 are configured to output the operating voltage and the digital call signal together.

And detecting the current signal output from the fire detector separately at the (-) terminal of the loop A terminal 31 and the (-) terminal of the loop B terminal 32, respectively, thereby disconnecting somewhere in the communication loop 10. Even if this occurs, the operating voltage and the digital call signal can be supplied to all fire detectors in the communication loop 10. In addition, by configuring each of the (-) terminal of both ends of the communication loop 10 independently to detect the current signal, it is possible to obtain the measured values output from all the fire detectors.

For example, if the fire detector ① is called from the digital call signal while the operating voltage is being applied to each (+) terminal, the fire detector ① outputs the measured value as a current signal, and the output current signal is output to the loop A terminal. It can be detected simultaneously at the negative terminal and the negative terminal of the loop B terminal. The fire detector ① stops outputting the current signal when its call ends in the digital call signal.

Then, if the digital call signal calls the fire detector ② while the operating voltage is still applied, the fire detector ② outputs the measured value as a current signal, and the output current signal is detected at both negative terminals.

Similarly, if the fire detector ③ or the fire detector ④ is selected, the unselected detector stops outputting the current signal, and the current signal output from the called detector can be detected at both negative terminals.

FIG. 7 is a view for explaining the operation of each terminal in the case of outputting a digital call signal for selecting the operating voltage and the fire detector ② from the positive terminals on both sides of the loop as shown in FIG.

First, FIG. 7 (a) shows a positive terminal and a negative terminal of a loop A terminal, a positive terminal of a loop B terminal, and a case where the fire detector ② operates when the communication loop is normally connected. -) It shows the operation of the terminal, indicating that the operating voltage and digital call signal will be normally output at each (+) terminal, and that the current signal can be detected normally at each (-) terminal.

Next, Fig. 7 (b) shows a signal at each terminal when the line between the fire detector ② and the fire detector ③ is broken in the communication loop as shown in Fig. 7 (c). Even if the communication loop is disconnected, the operating voltage and the digital call signal are normally applied at each positive terminal to supply voltage to each fire detector. However, the current signal may be detected only at the negative terminal of the loop A terminal and the negative terminal of the loop B terminal.

Thus, since either current terminal can sense a current signal, even if the communication loop is disconnected, there is no problem in the operation of the system.

On the other hand, when a communication line is disconnected, according to the fire detection alarm system which concerns on this invention, it is also possible to determine the position of a disconnection. For example, if the communication line is disconnected as described above, when the current signal is output from the fire detector ②, the current signal can be detected at the negative terminal of the loop A terminal, but not at the negative terminal of the loop B terminal. The current signal will not be detected. In addition, if the current signal is output from the fire detector ③, the current signal may not be detected at the negative terminal of the loop A terminal, and the current signal may be detected only at the negative terminal of the loop B terminal.

If such a relationship is used, it is possible to determine at which position of the communication line a break occurs, which is advantageous for maintenance of the communication line.

Claims (5)

A communication loop including a positive line for transmitting a predetermined operating voltage and a digital call signal, and a negative line arranged in parallel with the positive line and becoming a reference voltage of the positive line;
A sensor connected to the (+) line and the (-) line of the communication loop and driven by the operating voltage of the (+) line to sense a fire occurrence condition from the surrounding environment and generate a measurement value; And analyzing the digital call signal of the (+) line to generate a current signal representing the measured value by varying the current flowing from the (+) line to the (-) line at the time it is called. Including a fire detector;
A control communication terminal for receiving the digital call signal, a power supply terminal for receiving the operating voltage, a loop A terminal connected to one end of the (+) line and the (-) line of the communication loop, A loop B terminal to which the other end of the (+) line and the (-) line of the communication loop are connected, the operating voltage and the digital call signal are output from each of the (+) lines, and from each of the (-) lines An interface unit including an MCU which, upon receiving the current signal, converts the received current signal into the measured value of a corresponding fire detector and outputs it through the control communication terminal; And
Connected to the interface unit via the control communication terminal, providing the digital call signal to the interface unit for calling the fire detector, receiving the measured value from the called fire detector and inputting in advance A fire detection alarm system with a bidirectional communication loop including a main control panel for performing programmatic processing. The method of claim 1,
The interface unit comprises a positive circuit of the (+) terminal of the loop A terminal and a (+) terminal of the loop B terminal, and outputs the operating voltage and the digital call signal simultaneously at each (+) terminal. And separately detecting the current signal at each of the (-) terminal of the loop A terminal and the (-) terminal of the loop B terminal, and the (-) terminal of the loop A terminal and the (-) terminal of the loop B terminal. A fire detection alarm system having a two-way communication loop characterized by combining each current signal detected at the terminal. The method of claim 1,
And said digital call signal is modulated with said operating voltage as a carrier. The method of claim 1,
The fire detector comprises:
At least one of a smoke detector for detecting the occurrence of smoke, a temperature detector for detecting the ambient temperature, a flame detector for detecting the occurrence of flame, an emergency manual push switch that can be operated manually in the event of an emergency, and a timer for timing a set time. Fire detection alarm system having a two-way communication loop, characterized in that it comprises one. The method of claim 1,
The fire detector comprises:
And a filter for separating the digital call signal from the operating voltage of the communication loop.

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