KR20020014632A - Disaster prevention system - Google Patents

Abstract

PURPOSE: A disaster preventing system is provided to more stably and quickly put out a fire and take shelter by implementing a dual warning system having a warning device and a display unit in a fire signal processing system as well as in a fire signal relay system. CONSTITUTION: A fire sensing system(100) is installed in every room of a building. A fire signal relay system(200) is installed at every 25m on each floor. A fire signal processing system(300) is installed in a controlling part of a building. The fire signal processing system(300), as well as the fire signal relay system(200), includes a warning device and a display unit, making a dual warning system. A fire signal is transmitted between the fire sensing system(100) and the fire signal relay system(200) by a public wave method through antennas(102, 104) by a radio communication method. A fire signal is transmitted and received between the fire signal relay system(200) and the fire signal processing system(300) by a power line communication method by using a DTMF signal as a carrier for modulating the fire signal by the medium of a general AC power. A controller(314) of the fire signal processing system(300) has a program to provide a fire occurrence information for recognizing an accurate fire occurrence position to a fire putting out agency such as a fire station for a quick disaster preventing process. A DC power supply unit(216) is installed at the fire signal processing system(300) to supply a DC power required for transmission and reception of the fire signal through the power line in the case of power failure.

Description

Disaster Prevention System {DISASTER PREVENTION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disaster prevention system, and more particularly, to a disaster prevention system that transmits and receives a fire signal through a power line using AC commercial AC power as a transmission medium.

In general, a disaster prevention system detects heat or smoke to generate a fire signal, a repeater for wirelessly receiving the fire signal, and a fire detection to determine a precise fire location by analyzing a fire signal from the repeater. It consists of a receiver.

Such a disaster prevention system is disclosed in Korean Patent Publication No. 99-24118. In the present invention, as shown in Figure 1, each sensor 20 is configured to give a unique identification code and transmit it to the repeater 30 using a wireless communication (50). Therefore, since the fire signal is wirelessly communicated, there is no need to separately establish a signal transmission line between the alarm generating device of the detector and the repeater, and it is advantageous in that the exact location of the fire occurrence can be grasped.

However, in the above-described conventional technology, a signal transmission line 40 which is a wired line is provided between the repeater 30 and the fire detection receiving panel 10. As such, installation and design costs are increased due to the installation of a separate signal transmission line, and even if a telephone line is already installed, signal transmission may not be possible due to disconnection of a fire.

Therefore, even if the alarm sounds by the repeater, the information on the occurrence of the fire and the location of the fire cannot be properly transmitted to the fire suppression engine such as a fire station, so that a rapid response to the fire is impossible.

The present invention has been made to overcome the above-mentioned conventional problems, and an object of the present invention is to provide a novel disaster prevention system of a dual alarm system that is completely different from the above-described conventional disaster prevention system.

Another object of the present invention is to provide a disaster prevention system that does not require a separate signal transmission line.

Still another object of the present invention is to provide a disaster prevention system in which construction and maintenance costs are reduced.

The above-described object is achieved by the technical idea of the present invention. According to a feature of the present invention, a sensor for detecting a fire when a fire is generated is provided with a fire generation detection system 100 for generating a fire signal, and the fire A fire signal relay system 200 that transmits a fire signal generated from an occurrence detection system or generates an alarm, and a fire signal process that detects a fire signal received from the fire signal relay system and outputs fire location information and a fire alarm. The system 300 is provided, the fire signal relay system 200 and the fire signal processing system 300 is interconnected by a power line 106 for supplying AC commercial AC power, the fire signal is connected to the power line There is provided a disaster prevention system that is transmitted and received through.

In the present invention, the power line is preferably provided with a DC power supply unit 216 for supplying a DC power required for transmitting and receiving a fire signal in the event of a power outage due to fire.

In addition, between the fire signal relay system 200 and the fire signal processing system 300, it is preferable that power line communication interface units 214 and 302 are provided to enable power line transmission and reception of fire signals.

In addition, the fire occurrence detection system 100,

When a fire is detected from the sensor 110, a code generator 116 for generating an identification code signal unique to a detection system, an oscillator 114 for generating an analog signal, and a radio wave form by combining the identification code signal with the analog signal. According to the modulator 118 for frequency modulation, the RF amplifier 120 for amplifying to a signal level required for transmission, and a band pass that removes noise generated in a signal and outputs a signal having a predetermined bandwidth through the transmission antenna 102. Filter 122,

The fire signal relay system 200,

A receiving antenna 104 for receiving a fire signal transmitted wirelessly; a high frequency amplifier 202 connected to the receiving antenna to amplify a frequency of the received signal; and a receiving frequency to facilitate amplification and selection of the high frequency amplified signal. A frequency converter 204 for converting to an intermediate frequency, a carrier transmitter 208 for amplifying and transmitting the frequency-converted signal to transmit a signal to a power line, and interfacing and transmitting the output signal of the carrier transmitter to a commercial AC power source of the power line; On the contrary, a first power line communication interface unit 214 for receiving a signal of a carrier wave carried on the power line by interfacing to a commercial AC power source of the power line, receiving an output from the first power line communication interface unit, and outputting a fire signal to the first display unit 212. Connected to the carrier receiver 210 and the power line 106 to be displayed on the Is composed of a DC power supply unit 216 for supplying a direct current power necessary for the transmission and reception of signals,

The fire signal processing system 300,

A second power line communication interface unit 302 and a second power line communication interface unit for interfacing and transmitting an output signal of a carrier wave to a commercial AC power source of a power line, or conversely receiving and receiving a signal of a carrier wave loaded on a power line to a commercial AC power source of a power line; A carrier receiver 304 for amplifying the output from the frequency converter, a frequency converter 308 for converting the output signal of the carrier receiver to an intermediate frequency for easy amplification and selection, and generating a modulated signal used in the fire detection detection system 100 And a frequency discriminator 310 for reproducing the original signal from which the modulated signal has been removed from the received signal by a product of the modulated signal and the received signal converted into an intermediate frequency by the frequency converter 308, and the frequency discriminator. A code analysis processor 312 which separates and transmits a code signal among signals reproduced from the device 310, and the code The first display unit of the fire signal relay system 200 is driven through the power line 107 while the second display unit 316 is driven while comparing the code signal received from the analysis processor 312 with a code stored in advance. It is preferably configured as a control unit 314 for driving (212).

The carrier is preferably a DTMF signal used for telephone dialing.

1 is a block diagram of a disaster prevention system configuration according to the prior art.

2 is a block diagram of a disaster prevention system configuration according to the present invention.

3 is a block diagram of a fire occurrence detection system configuration according to the present invention.

4 is a block diagram of a fire signal relay system configuration according to the present invention.

5 is a block diagram of a fire signal processing system configuration according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: fire occurrence detection system

200: fire signal relay system

300: Fire Signal Processing System

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. From the following description, the characteristic configurations of the present invention described above will be readily understood.

2 shows a block diagram of a disaster prevention system configuration according to the present invention.

As shown in FIG. 2, the disaster prevention system according to the present invention includes, for example, a fire generation detection system 100 that can be installed in each room of a building, and a fire that can be installed on each floor, for example, at intervals of 25 m, for example, in a corridor of a building. The signal relay system 200 and the fire signal processing system 300 that can be installed in the control unit of the building, such as a water level room.

In particular, in the configuration of the present invention, not only the fire signal relay system 200 but also the fire signal processing system 300 has a dual alarm system provided with an alarm device and a display unit, respectively.

In addition, the fire occurrence detection system 100 and the fire signal relay system 200 are transmitted and received the fire signal by the "airwave method" through the antenna 102, 104 by a wireless communication method, the fire signal relay system 200 The fire signal is transmitted and received between the and the fire signal processing system 300 by a "power line communication system" using a DTMF signal as a carrier for modulating a fire signal, using a commercial AC power source as a medium.

In addition, the control unit 314 of the fire signal processing system 300 is programmed to provide a fire suppression engine, such as a fire station, to provide a fire occurrence information that can determine the exact location of the fire is to enable rapid disaster prevention processing.

In addition, the fire signal processing system 300 is provided with a DC power supply unit 216 for supplying a DC power required for the transmission and reception of a fire signal through the power line in the event of a power outage due to fire.

Configuration and operation of each system according to the present invention as described above will be described in more detail through the remaining drawings.

Figure 3 shows the configuration of the fire occurrence detection system of the disaster prevention system according to the present invention.

As shown in FIG. 3, the fire occurrence detection system 100 of the present invention includes a battery 108, a sensor 110, a power control unit 112, an oscillator 114, a code generator 116, and a modulator 118. ), An RF amplifier 120, a BPF 122, and a transmission antenna 102.

The battery 108 supplies power to the sensor 110, the oscillator 114, and the code generator 116.

The power control unit 112 controls the power supply of the battery 108. In normal operation, the power control unit 112 supplies power only to the circuits of the sensor 110, and in case of abnormality, the power supply is supplied to all the circuits to minimize the use power. .

The sensor 110 detects the occurrence of fire with a fire detection sensor and generates a fire signal that is a detection signal. In this case, the sensor is generally classified into a smoke sensor and a temperature sensor according to a form of detecting a fire occurrence. The smoke sensor acts as an electronic switching by the smoke particles cause the ionization phenomenon in the sensor to change the capacity of the capacitor during the fire. The temperature sensor serves as a switching due to thermal expansion due to temperature. However, depending on the use of the sensor, not only smoke or temperature, but also the state of opening and closing of the emergency door, the presence or absence of infrared rays, theft, gas, etc. can be detected.

The code generator 116 is composed of a one-chip microprocessor, and a unique ID code for identifying the sensor is input in advance by an external input. This ID code contains location information such as an address or telephone number. Therefore, the code generator 116 generates a unique ID code input by the detection signal according to the fire occurrence from the sensor 110.

The oscillator 114 is driven by a power source supplied when detecting a fire to generate a high frequency ID code signal from the code generator 116 wirelessly, thereby generating an analog signal of high frequency, that is, a modulated signal.

The modulator 118 takes an analog signal from the oscillator 114 and an ID code from the code generator 116 as input and modulates it according to the air wave propagation formats such as F1D, F2D, and A1D.

The RF amplifier 120 amplifies the signal modulated by the modulator 118 so that the signal to be transmitted wirelessly can reach the receiver stably.

The BPF 122 suppresses noise included in the amplified signal and transmits a signal having a predetermined bandwidth.

The transmit antenna 102 wirelessly transmits a signal in which a code signal modulated to an analog signal is amplified by the RF amplifier 120. This radio signal is transmitted to the receiving antenna 104 of the fire signal relay system 200 to be described with reference to FIG.

Figure 4 shows the configuration of the fire signal relay system of the disaster prevention system according to the present invention.

The fire signal relay system 200 illustrated in FIG. 4 includes a reception antenna 104, a frequency converter 204, an emergency bell switch 206, a carrier transmitter 208, a carrier receiver 210, and a first display unit 212. And a first power line communication interface unit 214, power lines 106 and 107, and a DC power supply unit 216.

First, the receiving antenna 104 receives a signal transmitted from the transmitting antenna 102 of the fire occurrence detection system 100.

The high frequency amplifier 202 is composed of an input circuit and a high frequency amplifying circuit. Since the strength of the signal received from the antenna 104 is weak, the high frequency amplifier 202 is amplified sufficiently large to demodulate the original signal to the frequency converter 204. To send).

The frequency converter 204 converts the reception frequency into an intermediate frequency to facilitate amplification and selection of the received signal.

The carrier transmitter 208 amplifies and transmits the frequency converted signal to transmit the signal to the power line.

Meanwhile, in the present invention, a dual tone multi frequency (DTMF) signal is used as a carrier wave for transmitting and receiving signals between the fire signal relay system 200 and the fire signal processing system 300. DTMF signal is composed of 4 kinds of low frequency group and 4 kinds of low frequency group and is a complex frequency signal made by mixing 1 low frequency group and 1 high frequency group. As described above, the use of the DTMF signal is possible because various kinds of information control are possible and suitable for the remote control method using the line. However, not only DTMF signals but also other types of signals may be applied as carriers.

An emergency bell switch 206 is placed between the frequency converter 204 and the carrier transmitter 208. That is, the emergency bell switch 206 can be operated when the fire is detected by a person near the fire signal relay system 200 is installed.

The first power line communication interface unit 214 may be composed of a coupling transformer and two coupling capacitors. The first power line communication interface unit 214 may interface the transmission signal of the carrier transmitter 208 to a commercial AC power supply of the power line 106, or, conversely, the power line ( The carrier signal shown in 107 is interfaced to and received from a commercial AC power source of a power line. That is, the output signal of the carrier transmitter 208 is transmitted and received by the interface unit 214 in synchronization with a sine wave of 60 Hz, which is a commercial AC power source. Since the power lines 106 and 107 do not need to connect a separate communication line because all power lines in the home or office become communication lines, the cost of installing and constructing the communication lines is reduced.

Subsequently, a DC power supply 216 is connected to the power lines 106 and 107, which are automatically switched in the event of a power outage due to a fire to supply DC + 12V and + 5V to the power line.

The carrier receiver 210 receives a signal output from the interface unit 214 and transmits the signal to the first display unit 212.

The first display unit 212 includes a liquid crystal display, a warning light, an alarm, and the like, and displays a fire occurrence address, a telephone number, etc. by a fire signal processed by the control unit 314 from the fire signal processing system 300 described later. At the same time, an alarm light and an alarm sound are generated.

Figure 5 shows the configuration of a fire signal processing system of the disaster prevention system according to the present invention.

The fire signal processing system 200 illustrated in FIG. 5 includes a second power line communication interface 302, a carrier receiver 304, a carrier transmitter 306, a frequency converter 308, a frequency discriminator 310, and code analysis. It consists of a processing unit 312, a control unit 314, a second display unit 316, and a ROM data unit 318.

Since the second power line communication interface unit 302 has the same structure and function as the above-described first power line communication interface unit 214, description thereof will be omitted.

The carrier receiver 304 transmits the output signal of the interface unit 302 to the frequency converter 308.

The frequency converter 308 converts the reception frequency into an intermediate frequency to facilitate amplification and selection of the received signal received from the power line.

The frequency discriminator 310 generates a modulated signal used in the fire occurrence detection system 100 and receives the received signal by the product of the modulated signal and the received signal converted to an intermediate frequency by the frequency converter 308. To generate the original signal from which the modulated signal has been removed.

The code analysis processing unit 312 interprets the code signal from the original signal reproduced by the frequency discriminator 310 and transmits the code signal to the control unit 314.

The control unit 314 is composed of a one-chip microprocessor and determines whether the code signal input from the code analysis processing unit 312 matches the code input to the ROM data unit 318, and if it matches, the transmitted signal is a fire signal. The controller recognizes the fire alarm through the second display unit 316, and if it is wrong, considers it as a signal transmitted from a system of another system and stops further code determination.

The ROM data unit 318 has a preset code and an operation program embedded therein, and instructs the control unit 314 in various actions. That is, the operation program is programmed to cause the control unit 314 to display the fire alarm on the second display unit 316, to communicate with a fire suppression engine such as a fire station, and to communicate with the landlord by telephone. In addition, the ROM data unit 318 is configured such that the control unit 314 detects a code signal from the code analysis processing unit 312 as a fire signal and fires in response to the code signal when the fire signal is detected. Information such as the location of occurrence should be stored.

The second display unit 316 includes a liquid crystal display, a warning light, an alarm, and the like, and is driven by a fire signal of the controller 314 to display whether a fire has occurred and a location where the fire has occurred.

Meanwhile, after the fire signal of the controller 314 is amplified by the carrier transmitter 306 again, the first display unit 212 via the second power line communication interface unit 302, the power line 107, and the carrier receiver 210. Is sent). As described above, the first display unit 212 of the fire signal relay system displays a fire occurrence address, a telephone number, and the like, and generates an alarm light and an alarm sound at the same time.

As described above, according to the above-described configuration of the present invention, since not only the fire signal relay system 200 but also the fire signal processing system 300 each have a dual alarm system provided with a separate alarm device and a display unit, it is safer and faster. The fire can be suppressed and evacuated.

In addition, the fire generation detection system 100 and the fire signal relay system 200 is a radio signal transmission and reception through the antenna 102, 104 by a wireless communication method, the fire signal relay system 200 and the fire signal processing system ( Between 300), the fire signal is transmitted and received by the power line communication method using a commercial AC power supply as a carrier and DTMF signal as a carrier wave, thus preventing fire detection failure due to disconnection and preventing material and labor costs for installation and repair. Can be reduced.

In addition, the control unit 314 of the fire signal processing system 300 is programmed to provide a fire suppression engine, such as a fire station, to provide a fire occurrence information that can determine the exact location of the fire, to enable a quick and accurate disaster prevention processing do.

In addition, the power line is provided with an emergency DC power supply unit 216 for supplying the DC power required for the transmission and reception of fire signals, so that transmission and reception through the power line is possible even in the event of a power failure due to fire.

What has been described above is only one embodiment for implementing the disaster prevention system according to the present invention, the present invention is not limited to the above embodiment.

For example, in the embodiment of the present invention, although the fire occurrence detection system 100 and the fire signal relay system 200 are transmitted and received by an air wave method, as in the fire signal relay system 200 and the fire signal processing system 300. Transmission and reception using power line is possible.

In addition, in the embodiment of the present invention, transmission and reception to and from the control unit 314 and the fire suppression engine may be implemented through a power line.

In addition, in the embodiment of the present invention, the power line is dually configured to transmit and receive a fire signal, but may be configured to enable bidirectional communication with one power line.

In addition, in the embodiment of the present invention, the fire signal by the control unit 314 is not only provided to the display units 212 and 316, but may be configured to automatically call the fire station through the telephone line.

Accordingly, the technical spirit of the present invention can be variously modified by anyone having ordinary skill in the art without departing from the gist of the present invention as claimed in the following claims.

Claims (5)

A fire generation detection system 100 for generating a fire signal by installing a sensor for detecting a fire when a fire occurs; A fire signal relay system 200 for transmitting a fire signal generated from the fire occurrence detection system or generating an alarm; It is provided with a fire signal processing system 300 for grasping the fire signal received from the fire signal relay system and outputs fire location information and fire alarm, The fire signal relay system 200 and the fire signal processing system 300 are interconnected by a power line 106 for supplying AC commercial AC power, disaster prevention, characterized in that the fire signal is transmitted and received through the power line system. The disaster prevention system according to claim 1, wherein the power line is provided with a DC power supply unit (216) for supplying DC power required for transmission and reception of a fire signal in case of a power failure due to a fire. The power line communication interface unit 214 or 302 is provided between the fire signal relay system 200 and the fire signal processing system 300 to enable power line transmission and reception of fire signals. Disaster prevention system to make. The method of claim 1, The fire occurrence detection system 100, When a fire is detected from the sensor 110, a code generator 116 for generating an identification code signal unique to a detection system, an oscillator 114 for generating an analog signal, and a radio wave form by combining the identification code signal with the analog signal. According to the modulator 118 for frequency modulation, the RF amplifier 120 for amplifying to a signal level required for transmission, and a band pass that removes noise generated in a signal and outputs a signal having a predetermined bandwidth through the transmission antenna 102. Filter 122, The fire signal relay system 200, A receiving antenna 104 for receiving a fire signal transmitted wirelessly, a high frequency amplifier 202 connected to the receiving antenna to amplify the frequency of the received signal, and converting to an intermediate frequency for easy amplification and selection of the high frequency amplified signal The frequency converter 204, a carrier transmitter 208 for amplifying and transmitting the frequency-converted signal to transmit a signal to a power line, and interfacing and transmitting the output signal of the carrier transmitter to a commercial AC power source of the power line or vice versa. A first power line communication interface unit 214 for interfacing and receiving the signal of the carried carrier to a commercial AC power source of the power line, and receiving an output from the first power line communication interface unit to display a fire signal on the first display unit 212; It is connected to the carrier receiver 210 and the power line 106 to transmit and receive the fire signal in case of power failure due to the fire Is composed of a DC power supply unit 216 for supplying a direct current power required, The fire signal processing system 300, A second power line communication interface unit 302 and a second power line communication interface unit for interfacing and transmitting an output signal of a carrier wave to a commercial AC power source of a power line, or conversely receiving and receiving a signal of a carrier wave loaded on a power line to a commercial AC power source of a power line; A carrier receiver 304 for amplifying the output from the frequency converter, a frequency converter 308 for converting the output signal of the carrier receiver to an intermediate frequency for easy amplification and selection, and generating a modulated signal used in the fire detection detection system 100 And a frequency discriminator 310 for reproducing the original signal from which the modulated signal has been removed from the received signal by the product of the modulated signal and the received signal converted into an intermediate frequency by the frequency converter 308, the frequency unit Code analysis processing unit 312 for separating and transmitting the code signal of the signal reproduced from the discriminator 310, the code The first display unit of the fire signal relay system 200 is driven through the power line 107 while the second display unit 316 is driven while comparing the code signal received from the analysis processor 312 with a code stored in advance. Disaster prevention system characterized by comprising a control unit (314) for driving (212). The disaster prevention system according to claim 4, wherein said carrier is a DTMF signal used for telephone dialing.