KR101684366B1 - Apparatus for supervising fire using telecommunication net of apartment house - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates to a fire monitoring apparatus for fire fighting using a communication network of a multi-house house. Even if a fire signal is detected from a plurality of sensors, the fire signal is transmitted wirelessly without errors, A fire signal detection device for performing a fire detection; The digital code received from the fire signal sensing device is decrypted to provide a fire action command to the correct fire occurrence location by the sensor unique code indicating each sensor and at the same time digital wireless communication is performed bidirectionally with the transmitter while performing transmission / A fire signal processing device; An intensive injector for intensively injecting the extinguishing water to the fire occurrence position detected by the fire signal detecting device and evolving to a fire golden type at the initial stage of the fire before the fire is diffused; And centralized ejection device control means for controlling the horizontal rotation means in accordance with an output signal of the fire occurrence alarm portion / fire occurrence position indication portion; , It is possible to minimize the loss of life and property caused by the fire by performing rapid initialization within the fire golden time in the early stage of fire by injecting the fire water into the ignition point intensively by operating a plurality of central injection devices installed in each zone .

Description

FIELD OF THE INVENTION [0001] The present invention relates to a fire monitoring system for fire-

The present invention relates to a fire detection device for fire fighting using a communication network of a multi-family house among fire fighting techniques, more specifically, to set a hazardous area and other non- A plurality of sensors are installed in each of the zone and the non-hazardous area. A plurality of concentrated spraying devices for intensively spraying the water and a plurality of common sprinklers for spraying the water are arranged. The fire-fighting fire monitoring system using the communication network of the apartment building that minimizes the loss of life and property caused by the fire by early initialization in the fire golden time by intensively injecting the fire water into the ignition point by operating the central injection device ≪ / RTI >

In general, when a fire occurs in each household of a multi-family house, if a resident is staying in a household in a fire-generation household, the resident evolves using a fire extinguisher, while a fire is reported to 119 and escapes in a dangerous situation If a resident of a household is absent, it is impossible to go through the above-mentioned coping process. Therefore, when a fire is detected to some extent and fire, heat or smoke is detected by the fire detection sensor, a fire alarm device When a fire is reported to 119 by a resident of another household or a management office or a security guard in the vicinity, fire trucks and firefighters are dispatched and the fire process is evolved. In this case, considerable time It will start to evolve only after the passage of time. The damage caused by the fire and there is a problem that increases.

Accordingly, in the related art, when a fire occurs in a apartment house, a system for notifying a resident of a fire occurrence and a situation using a mobile communication network and reporting a fire at 119 is disclosed. However, even in this case, In this case, since it takes time until the fire starts to evolve by the time required for dispatching the fire truck and the firefighting team, there is a problem that the fire is greatly spread and the damage is increased.

In general, the time to minimize the damage caused by fire, that is, the fire golden time is 5 to 10 minutes, and it is practically impossible to evolve within the fire golden time as the conventional system described above.

Therefore, it is required to develop the technology that can minimize the damage caused by the fire by evolving quickly in the early stage of the fire regardless of the presence or absence of the residents.

As a prior art, Korean Patent Laid-Open Publication No. 10-1999-0024118 (Mar. 25, 1999) discloses a method and system for transmitting fire detection signals (hereinafter referred to as "Prior Art 1"), A unique ID is assigned to each detector of the fire detector, and when a sensor detects a fire occurrence, the detector wirelessly transmits a unique ID code and a fire occurrence signal to the repeater, and judges whether the ID code stored in the self- A fire alarm can be output to prevent a fire detection failure due to disconnection to a signal transmission line, and an alarm output can be taken to take measures against a fire occurrence and to identify an accurate fire occurrence location.

However, there is a disadvantage in that it is not operated as a crosstalk when there is a transmission signal generated simultaneously in a plurality of fire detectors, and a problem that a plurality of fire detection signals for the received signal can not be processed by a program built in the microprocessor of the receiver In addition, the wired fire detection system may fail to detect a fire due to disconnection, and can not provide comprehensive fire occurrence status information such as temperature detection, smoke detection, and heat detection.

An intelligent fire detection system using wireless communication (hereinafter referred to as " Prior Art 2 ") as a prior art that solves such a problem is disclosed in Korean Patent No. 10-0300160 A fire signal detection system for performing a digital wireless communication with the receiver in both directions while performing a transmission / reception mode conversion while transmitting a fire signal wirelessly without error even if a signal is detected; And a fire signal processing system that performs digital wireless communication with the transmitter in both directions while performing a transmission / reception mode conversion while providing a fire action command at an accurate fire occurrence position by a sensor unique code indicating the sensor, And detects the fire signal through wireless communication. To send the system generates an accurate position indication, fire warning, fire alarm the fire by taking quick action on the fire it discloses a technique to reduce casualties and property damage.

However, in the prior art 2, the fire detection and the fire signal processing can be performed quickly and accurately without any errors, and the evolution of the fire is not required until the fire truck and the fire department arrive at the site It is impossible to start the initial evolution within the golden time of the fire in the early stage of the fire, so that the spread of the fire is inevitable and the conventional problem of increasing life and property damage due to the fire can not be solved.

Therefore, it is possible to prevent the spread of fire by performing rapid and intensive initial evolutions in the fire type fire type in the early stage of the fire without monitoring the fire occurrence and waiting for fire engine and firefighter to evolve the fire. It is required to develop a technology capable of minimizing damage to people and property.

Korean Patent Publication No. 10-1999-0024118 (published March 25, 1999) "Fire Detection Signal Delivery Method and System thereof" Korea Registered Patent No. 10-0300160 (registered on June 14, 2001) "Intelligent Fire Detection System using Wireless Communication"

Accordingly, it is an object of the present invention to provide a method of setting fire prevention zones and other non-danger zones in each household of a multi-family house, installing a plurality of sensors in each of the danger zones and non-hazard zones, And a plurality of common sprinklers for dispersing and extinguishing the extinguishing water are arranged. When a fire occurs, a plurality of central injectors installed in the respective areas are operated to concentrate the extinguishing water to the ignition point, The purpose of this study is to provide a fire monitoring system for firefighting using a communication network of a multi-family house, which is capable of minimizing the damage of persons and property due to fire by early early evolution in Golden Time.

According to the present invention, a fire signal sensed by a sensor is modulated and transmitted from a transmission antenna to a receiver, a transmitted fire signal is received through a reception antenna, A fire detection system for notifying a fire alarm system that a fire signal is transmitted wirelessly without any error even when a fire signal is detected from a plurality of sensors, Wow; The digital code received from the fire signal sensing device is decrypted to provide a fire action command to the correct fire occurrence location by the sensor unique code indicating each sensor and at the same time digital wireless communication is performed bidirectionally with the transmitter while performing transmission / A fire signal processing device; An intensive injector for intensively injecting the extinguishing water to the fire occurrence position detected by the fire signal detecting device and evolving to a fire golden type at the initial stage of the fire before the fire is diffused; And an intensive injection device control means for controlling the central injection device according to an output signal of the fire occurrence alarm portion / fire occurrence position instruction portion. Wherein the internal space of each household of the apartment house is set in advance as a dangerous zone in which there is a risk of fire and other non-dangerous zones, and the sensor is installed in each zone, and the centralized injection device A water supply line buried in a generation ceiling; An electromagnetic valve coupled to a lower end of the water supply pipe; A horizontal rotary pipe connected to the lower end of the electromagnetic valve so as to be horizontally rotatable; A minuscircular chamber provided between a lower end of the solenoid valve and an upper end of the horizontal rotary pipe; An upper end portion connected to a lower end of the horizontal rotary pipe and connected to a lower end of the horizontal rotary pipe, the upper end portion having a larger inner diameter and narrower downward, and a lower end portion formed at a lower end of the upper end portion, And a horizontal central injection hole horizontally formed on the upper side of the downward concentrated injection hole and opened at one side of the outer peripheral surface; A horizontal rotating means for rotating the horizontal rotary pipe; Wherein the rotary type central injection nozzle includes a downwardly focused injection hole and a horizontally centralized injection hole disposed below the ceiling half, and the horizontal rotation means includes a ring gear coupled to an outer peripheral surface of the horizontal rotary pipe; A driving motor installed perpendicular to the ceiling half; A driving gear fixedly mounted on a motor shaft of the driving motor; And a transmission gear engaged with the ring gear and the driving gear, wherein the centralized injection device control means controls the central injection device according to an output signal of a fire occurrence alarm portion / fire occurrence position instruction portion of the fire signal processing system, A centralized injection device controller for outputting an opening / closing control command and a rotation control command to the driving motor; An electromagnetic valve driving unit and a driving motor driving unit for sending an opening / closing driving signal to the electromagnetic valve and a rotation driving signal for the driving motor in accordance with a control command of the centralized injection device control unit; The present invention provides a fire monitoring apparatus for fire fighting using a communication network of a multi-family house.

According to the fire monitoring system for fire fighting using the communication network of the apartment house of the present invention, even when a fire signal is detected from a plurality of sensors, the fire signal is transmitted wirelessly without error, and at the same time, A fire signal sensing device performing; The digital code received from the fire signal sensing device is decrypted to provide a fire action command to the correct fire occurrence location by the sensor unique code indicating each sensor and at the same time digital wireless communication is performed bidirectionally with the transmitter while performing transmission / A fire signal processing device; An intensive injector for intensively injecting the extinguishing water to the fire occurrence position detected by the fire signal detecting device and evolving to a fire golden type at the initial stage of the fire before the fire is diffused; And centralized ejection device control means for controlling the horizontal rotation means in accordance with an output signal of the fire occurrence alarm portion / fire occurrence position indication portion; , It is possible to minimize the loss of life and property caused by the fire by performing rapid initialization within the fire golden time in the early stage of fire by injecting the fire water into the ignition point intensively by operating a plurality of central injection devices installed in each zone .

1 to 6 show a preferred embodiment of a fire monitoring apparatus for fire fighting using a communication network of a multi-family house according to the present invention,
1 is a functional block diagram of a fire signal sensing apparatus,
2 is a functional block diagram of the fire signal processing device and the centralized injection device control means,
3 and 4 are perspective views seen from different directions of the centralized injection device,
5 is an exploded perspective view of the centralized injection device,
6 is a plan view showing an arrangement state of the centralized spray device and the general sprinkler.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fire monitoring system for fire fighting using a communication network of a multi-family house according to the present invention will be described in detail with reference to the preferred embodiments illustrated in the accompanying drawings.

1 to 6 show a preferred embodiment of a fire monitoring system for fire fighting using a communication network of a multi-house according to the present invention.

The fire monitoring apparatus for fire fighting using the communication network of the apartment house according to the present embodiment includes a fire signal detecting apparatus 100 and a fire signal processing apparatus 200.

The fire signal sensing apparatus 100 includes a sensor 101, a controller processor 102, a signal conversion / waveform shaping unit 103, a frequency synthesizer / modulator 104, a buffer amplifier 105, a power amplifier 106, a changeover switch 107, a band pass filter / low pass filter (BPF / LPF) 108, an RF detector 109, a power supply control section 110, 111).

The sensor 101 detects signals of temperature sensing, heat sensing, smoke sensing, opening / closing of emergency doors, detecting presence / absence of infrared rays, presence of objects (stolen), gas, 102).

The sensor 101 is a fire detection sensor, typically a smoke sensor and a constant temperature sensor. The smoke sensor causes an ionization phenomenon in a sensor when a fire occurs, thereby causing a capacity change of the condenser to act as an electronic switch. The constant temperature sensor serves as a switch according to thermal expansion due to temperature.

Therefore, since the switch is opened in the normal state and the power supply of the transmitter is interrupted, the use of the power source, which is one of the problems of the electroless fire detector, can be minimized.

The controller processor 102 is comprised of a one-chip microprocessor, and the ROM memory of the processor contains a code representing each fire detector and an operating program.

The code may consist of a start bit, a recognition byte, a unique code byte, and a termination bit.

Upon receipt of a request to start the program from the sensor 101, the operating program determines whether or not there is a signal sent from the RF detector 109 (a signal is sent if there is a carrier wave of the used band around the antenna, and a signal is not sent if there is no carrier wave) , If there is no signal, the built-in code is repeatedly output at a fixed speed several times and waits for a predetermined time. If there is no signal after a certain time, the code is output again. This allows the fire signal from several fire detectors to be shared in a timely manner to be transmitted and received.

The signal conversion / waveform shaping unit 103 includes a signal polarity reversing circuit and a waveform shaping circuit. The signal conversion / waveform shaping unit 103 adjusts the mark frequency when the digital signal is 0 and the space frequency at 1, And the amplitude of the signal wave is kept constant to keep the deviation frequency at the specified value and to limit the occupied frequency band.

The frequency synthesizer / modulator 104 connects a voltage controlled oscillator (VCO) in a circuit to a frequency generator to generate a very stable oscillation frequency, and then outputs a code in the form of F1D, F2D, or A1D Modulate.

In the buffer amplifier 105, when the output circuit of the oscillation circuit is directly amplified, the parallel impedance changes. Therefore, the oscillation frequency may fluctuate. Therefore, the load and the oscillation portion are separated from each other so as not to be influenced.

The power amplifier 106 supplies power to the antenna so that the signal goes to the receiver.

The switch 107 is connected to the RF detector 109 which is a carrier frequency detection circuit in a steady state and is connected to the power amplifier 106 when a fire occurs and transmission is required. After a certain time, the RF detector 109 ) Is repeated.

The band pass filter (BPF) / low pass filter (LPF) 108 performs band filtering and low pass filtering to suppress noise generated.

The RF detector 109 senses the presence or absence of the carrier frequency being used and sends a signal to the controller processor 102 if it is present and does not send a signal if it is not present.

The power control unit 110 supplies power only to the RF detector 109 when it is in a normal state, and supplies power to all the circuits when it is abnormal, thereby minimizing power consumption.

The transmission antenna 111 transmits the fire detection signal modulated to an analog signal and wirelessly transmits the signal.

2, the fire signal processing apparatus 200 includes a receiving antenna 210, a high frequency amplifier 201, a double heterodyne receiver 202, a limiter 203, a frequency discriminator 204, Circuit 205, a low pass filter (LPF) 206, a trigger circuit 207, a code analysis and processing microprocessor 208, and a fire occurrence alarm / fire occurrence position instruction unit 209.

The high frequency amplifier 201 is composed of an input circuit and a high frequency amplifier. Since the strength of a signal received from the receiving antenna 210 is weak, the received signal is sufficiently large And provides it to the double heterodyne receiver 202.

The double heterodyne receiver 202 includes a frequency mixer, a local oscillator, and a bandpass filter. The double heterodyne receiver 202 converts a reception frequency to an intermediate frequency to facilitate amplification and selection of a received signal. .

The limiter 203 cuts off a certain level or more of the received signal to the double heterodyne receiver 202 so as not to affect the original signal even if noise in the received radio wave is added to the signal, do.

The frequency discriminator 204 converts the frequency change from the limiter 203 into a change in amplitude to reproduce the original signal.

The signal polarity reversal circuit 205 decodes the mark and space state of the original signal in the same manner as the frequency defined by the transmitter.

The low pass filter (LPF) 206 provides the output signal of the signal polarity inversion circuit 205 as a low-pass filtered signal.

The trigger circuit 207 receives the low-pass filtered signal as the originally transmitted digital code and provides it to the code interpretation and processing microprocessor 208.

The code analysis and processing microprocessor 208 is composed of a one-chip microprocessor and an operating program is embedded in the ROM memory. The operating program enters the preparation for reading the received digital code by the signal inputted from the trigger circuit 207. [ And then reads the digital code of the start bit that is subsequently input and then reads the recognition byte. These digital values determine whether the fire signal detection apparatus 100 and the fire signal processing apparatus 200 are in the same system. If the value of the recognition byte is compared with the built-in values, it is regarded as a signal transmitted from the fire signal sensing apparatus 100 of another system, and further decoding of the code is stopped. If they match, a unique code digital value indicating the location of the transmitting device is read and the exact fire location is determined. Then, one information signal reception is completed with the end bit.

In addition, the operating program embedded in the code analyzing and processing microprocessor 208 recognizes a fire condition, and then commands various actions as a next step. For example, it instructs the residents of the household in which the fire occurred, the apartment manager, and the fire department to make telephonic communications, open emergency doors, warning lights, warning sounds, and fire reports.

The fire alarm / fire occurrence position instruction unit 209 has an emergency power supply and displays an accurate position of a fire by a fire action command received from the code analysis and processing microprocessor 208, Emergency measures such as generating a fire alarm, making a telephone call, or opening an emergency door are performed.

On the other hand, the space within each household of the apartment house can be divided into a dangerous area where there is a relatively risk of fire such as a gas range installation area, a refrigerator installation area, a microwave installation area, and other non-hazardous areas. ) Is installed to detect a fire by a plurality of preset danger zones and a plurality of non-danger zones.

In addition, the sensor 101 may be installed more intensively with respect to the hazardous area than the non-hazardous area.

In addition, the fire monitoring apparatus for fire fighting using the communication network of the apartment house according to the present embodiment includes an intensive injector 300 for evolving a fire at the early fire golden time due to concentrated injection of the extinguished water to the ignition point at the beginning of the fire .

In the following description, the bolt through hole through which the bolt passes simply is shown in the drawing, but the reference numerals and explanations thereof are omitted.

The centralized injection device (300) includes a water supply pipe (310) embedded in a ceiling of each household of the apartment house; A solenoid valve 320 coupled to a lower end of the water supply pipe 310; A horizontal rotary pipe 330 coupled to the lower end of the solenoid valve 320 so as to be horizontally rotatable; A minuscircular chamber 340 installed between the lower end of the solenoid valve 320 and the upper end of the horizontal rotary pipe 330; A fire extinguishing water passage 351 coupled to a lower end of the horizontal rotary pipe 330 and connected to a lower end of the horizontal rotary pipe 330 and having an inner diameter larger and narrower at the lower part, And a horizontal concentration spray hole 353 horizontally formed on the upper side of the downwardly focused spray hole 352 and opened at one side of the outer peripheral surface of the downwardly focused spray hole 352. The downwardly focused spray hole 352, A rotary type centralized injection nozzle 350 provided with the rotary type central injection nozzle 350; A horizontal rotating means 360 for rotating the horizontal rotary pipe 330; .

The water supply pipe 310 is connected to a fire extinguishing water supply source (not shown) which is installed between the ceiling slab and the ceiling half and supplies the fire extinguishing water to the sprinkler head, and a detailed description thereof will be omitted.

The solenoid valve 320 may be a conventional solenoid valve. When the solenoid valve 320 is closed, the solenoid valve 320 is closed and the power is shut off. , And when the fire occurs, the power supply is shut off and is kept open.

This is to allow the solenoid valve 320 to be kept open even if the power is shut off due to a fire, so that operation can be performed even in case of a power failure due to fire.

The lower end of the water supply pipe 310 and the upper end of the electromagnetic valve 320 are connected to each other by a flange 311 formed at the lower end of the water supply pipe 310 and a bolt 321 passing through the flange 321 formed at the upper end of the electromagnetic valve 320 B1 and a nut N1 fastened thereto.

The lower end of the solenoid valve 320 and the horizontal rotary pipe 330 are connected to each other by a flange 322 formed at the lower end of the electromagnetic valve 320 and a flange 331 formed at the upper end of the horizontal rotary pipe 330, By coupling to the upper and lower ends of the mechanical seal 340, the horizontal rotation pipe 330 can be rotated relative to the electromagnetic valve 320, but no leakage occurs between them. The micaceous chambers 333 are generally rotatable relative to each other in connecting the two members, but are connected without any leakage of fluid. Therefore, detailed descriptions and explanations thereof will be omitted.

The coupling between the lower end of the electromagnetic valve 320 and the upper end of the mechanical chamber 340 is achieved by connecting a bolt B2 through the flange 322 formed at the lower end of the electromagnetic valve 320, The upper end of the micanical chamber 340 and the upper end of the horizontal rotary pipe 330 are connected to each other by a flange (not shown) formed at the upper end of the horizontal rotary pipe 330 331 to the screw hole 342 formed in the lower surface of the mechanical chamber 340.

The lower end of the horizontal rotary pipe 330 and the upper end of the rotary type central injection nozzle 350 are connected to each other by a flange 332 formed at the lower end of the horizontal rotary pipe 330 and a flange 332 formed at the upper end of the rotary concentrated injection nozzle 350 It may be formed by a bolt B4 passing through the flange 354 and a nut N4 fastened to the bolt B4.

The rotary concentrated injection nozzle 350 is provided with a downwardly focused injection hole 352 and a horizontal concentrated injection hole 353. Since the rotary concentrated injection nozzle 350 is installed on the ceiling, The ignition point of the downwardly focused injection hole 352 is initially set at a lower position than the ceiling so that the initialization of the ignition point is possible even if only the downwardly focused injection hole 352 is provided. It is preferable to further include the horizontal concentration spray hole 353 because evolution can not be achieved by the number of ions.

In this case, the injection angle of the extinguishing water sprayed from the downwardly concentrated spray hole 352 and the horizontal concentrated spray hole 353 is narrowed to about 2 to 10 degrees, so that the extinguishing water is not spread widely but is concentratedly injected to the ignition point .

The rotary concentrated injection nozzle 350 is installed such that the downwardly focused injection hole 352 and the horizontal concentrated injection hole 353 are positioned below the ceiling half P.

The horizontal rotation means 360 includes a ring gear 361 coupled to the outer circumferential surface of the horizontal rotation pipe 330; A drive motor 362 vertically installed on the ceiling half P; A driving gear 364 fixed to the motor shaft 363 of the driving motor 362; And a transmission gear 365 which meshes between the ring gear 361 and the drive gear 364.

Since the ring gear 361 can be coupled to the outer circumferential surface of the horizontal rotary pipe 330 by a conventional method such as key engagement or serration coupling, detailed illustration and description thereof will be omitted.

A motor base (not shown) is formed at the lower end of the driving motor 362, and the motor base can be fixedly mounted on the ceiling half P by a bolt / nut fastening method.

The coupling of the driving gear 364 with respect to the motor shaft 363 can be combined with a conventional shaft-gear coupling method such as a key coupling or a serration coupling. Therefore, detailed description thereof will be omitted.

The transmission gear 365 is rotatably supported by a shaft 366 fixed to a bracket 367 coupled to an upper surface of a driving motor 362.

An intensive injector control means (400) for controlling the central injection device (300) according to an output signal of the fire occurrence alarm portion / fire occurrence position instruction portion (209); .

The centralized injection device control means 400 controls the opening and closing control of the electromagnetic valve 320 and the operation of the drive motor (not shown) according to the output signal of the fire occurrence alarm portion / fire occurrence position instruction portion 209 of the fire signal processing device 200 A driving motor 362 for opening and closing the solenoid valve 320 according to a control command of the centralized injection device controller 410; And a drive motor driving unit 430. The solenoid valve driving unit 420 and the driving motor driving unit 430 transmit the rotation driving signal to the driving motor driving unit 430. [

As shown in FIG. 6, the centralized injection device 300 is installed on a ceiling together with a conventional sprinkler 500, and is disposed in consideration of a dangerous area and a non-hazardous area.

That is, the centralized injectors 300A, 300B, 300C and 300D are arranged corresponding to the plurality of danger zones Z1A, Z1B, Z1C and Z1D, respectively, and the normal sprinklers 500 ).

The centralized injectors 300A, 300B, 300C and 300D arranged in correspondence with the dangerous zones Z1A, Z1B, Z1C and Z1D are arranged in such a manner that, in the initial state, the downwardly directed concentrated spray holes 352 and the horizontally concentrated spray holes 353 correspond to each other Z1A, Z1B, Z1C, and Z1D.

6, solid line arrows show the directions of the inclined central injection holes 352 and the horizontal central injection holes 353 of the respective centralized injectors 300A, 300B, 300C and 300D.

At this time, the centralized injection device controller 410 receives the positional information of each of the dangerous zones Z1A, Z1B, Z1C and Z1D and the non-hazardous zone Z2 and the concentration information corresponding to each of the dangerous zones Z1A, Z1B, Z1C and Z1D The position information of the injection device 300 is stored and angle information for each of the dangerous zones Z1A, Z1B, Z1C and Z1D is stored in each of the centralized injection devices 300A, 300B, 300C and 300D.

The operation of the centralized injection device 300 and the centralized injection device control means 400 will be described below.

The inclined central injection hole 352 and the horizontal centralized injection hole 353 of each of the centralized injectors 300A, 300B, 300C and 300D are connected to the corresponding dangerous zones Z1A, Z1B, Z1C and Z1D For example, when a fire occurs in the hazardous area Z1A, the centralized injection device control unit 410 of the centralized injection device control means 400 receives the fire occurrence location information from the fire signal processing device 200 And outputs the opening control command to the electromagnetic valve 320 of the centralized injection device 300A corresponding to the fire dangerous area Z1A and outputs the opening control command to the solenoid valve driver 420 The solenoid valve 320 of the central injection device 300A is opened and the water of digestion water supplied from the water supply pipe 310 is discharged to the solenoid valve 320 of the central injection device 300A, (320), a horizontal rotary pipe (330), and a rotary atomizing nozzle And water supply to the reservoir 351, in which the concentration gradient injection port 352, and the horizontal focusing injection port 353, intensive early evolution of the ignition point is intensively sprayed with the fire early through will be written.

In addition, the centralized injection device control unit 410 outputs a rotation control command for the drive motors 362 of the centralized injection devices 300B, 300C and 300D corresponding to the dangerous zones Z1B, Z1C and Z1D in which no fire has occurred The driving motor driving unit 430 transmits a rotation driving signal to the driving motor 362 of the centralized injection devices 300B, 300C and 300D according to a control command of the centralized injection device control unit 410. [

At this time, the centralized injection device control unit 410 receives the position information of each of the dangerous zones Z1A, Z1B, Z1C, and Z1D and the non-hazardous zone Z2 and the centralized injection corresponding to each of the dangerous zones Z1A, Z1B, Z1C, and Z1D. Z1B, Z1C, Z1D) is stored in each of the centralized injection devices (300A, 300B, 300C, 300D) The rotation control command of the centralized injection device control unit 410 and the rotation drive signal of the drive motor drive unit 430 for the drive motor 362 of the control unit 300A, 300B, 300C, 300D are rotated at different angles.

When the drive motor 362 rotates, the drive gear 364 fixedly coupled to the motor shaft 363 rotates and the rotational force of the drive gear 364 is transmitted to the ring gear 361 via the transmission gear 365, The horizontal rotary pipe 330 to which the gear 361 is coupled and the rotary concentrated injection nozzle 350 coupled to the horizontal rotary pipe 330 rotate.

As a result, the inclined and concentrated injection holes 352 of the rotary type central injection nozzle 350 of the centralized injection devices 300B, 300C and 300D corresponding to the dangerous zones Z1B, Z1C and Z1D, The holes 353 are all directed to the dangerous zone Z1A where the fire has occurred.

At the same time, the centralized injection device control unit 410 outputs an opening control command to the solenoid valve 320 of the centralized injectors 300B, 300C, and 300D corresponding to the dangerous zones Z1B, Z1C, and Z1D in which no fire has occurred And the solenoid valve driver 420 sends an opening drive signal to the solenoid valve 320 so that the gradient concentration injection holes 352 and the horizontal concentration injection holes 353 of the central injection devices 300B, 300C, The fire extinguishing water is injected and the fire is generated by intensive injection into the dangerous zone Z1A.

Therefore, it is possible to prevent the spread of fire by rapidly evolving within the fire golden time at the initial stage of the fire due to intensive fire extinguishing of the fire dangerous area.

Herein, the digested water injected from the inclined central injection hole 352 is injected toward the ignition point lower than the ceiling, and the digested water injected from the horizontal concentration injection hole 353 is injected toward the ignition point on the ceiling side, It is possible to evolve effectively.

Since the micaceous chamber 340 is inserted between the electromagnetic valve 320 and the horizontal rotary pipe 330, the horizontal rotary pipe 330 can rotate relative to the electromagnetic valve 320, The leakage of water between the electromagnetic valve 320 and the horizontal rotary pipe 330 does not occur when the fire extinguishing water is supplied through the electromagnetic valve 320.

Also, even if a fire occurs in the non-hazardous zone Z2, rapid evoluation can be achieved within the fire golden time at the initial stage of the fire caused by the intensive fire extinguishing water injection as described above.

On the other hand, when the initial convergence by the centralized injection devices 300A, 300B, 300C, and 300D is not smooth and the fire is diffused, a normal sprinkler 500 is operated to disperse and extinguish the extinguished water Secondary fire evolves.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: fire signal detecting device 200: fire signal processing device
300: Centralized injection device 310: Water supply pipe
320: Solenoid valve 330: Horizontal rotating tube
340: Micanical chamber 350: Rotary type centralized injection nozzle
360: horizontal rotating means 361: ring gear
362: drive motor 364: drive gear
365: transmission gear 400: centralized injection device control means
410: Centralized injection device control part 420: Solenoid valve driving part
430: drive motor control section

Claims (1)

Modulates a fire signal sensed by the sensor 101, transmits the fire signal from the transmission antenna 111 to the receiver, receives the transmitted fire signal through the receiving antenna 210, and demodulates the fire signal to inform the fire occurrence position and the fire occurrence alert In a fire monitoring system for fire fighting using a communication network of a multi-
A fire signal sensing apparatus 100 for performing a digital wireless communication with a receiver while performing a transmission / reception mode conversion while wirelessly transmitting a fire signal without error even when a fire signal is detected from a plurality of sensors 101;
The digital code received from the fire signal sensing apparatus 100 is decoded to provide a fire action command at an accurate fire occurrence position according to the sensor unique code indicating each sensor 101, and at the same time, the transmitter and the bidirectional A fire signal processing device 200 for performing digital wireless communication with the fire signal processing device 200;
An intensive injector 300 for intensively injecting the extinguishing water to the fire occurrence position sensed by the fire signal sensing device 100 and evolving to a fire golden type at the initial stage of the fire before the fire is diffused; And
Centralized injection device control means (400) for controlling the central injection device (300) according to an output signal of a fire generation alarm / fire occurrence position designation unit (209); And,
The inner space of each household of the apartment house is set in advance as a dangerous zone in which there is a risk of fire and other non-dangerous zones, and the sensor 101 is installed in each zone,
The centralized injection device (300) includes a water supply pipe (310) embedded in a ceiling of each household of the apartment house; A solenoid valve 320 coupled to a lower end of the water supply pipe 310; A horizontal rotary pipe 330 coupled to the lower end of the solenoid valve 320 so as to be horizontally rotatable; A minuscircular chamber 340 installed between the lower end of the solenoid valve 320 and the upper end of the horizontal rotary pipe 330; A fire extinguishing water passage 351 coupled to a lower end of the horizontal rotary pipe 330 and connected to a lower end of the horizontal rotary pipe 330 and having an inner diameter larger and narrower at the lower part, And a horizontal concentration spray hole 353 horizontally formed on the upper side of the downwardly focused spray hole 352 and opened at one side of the outer peripheral surface of the downwardly focused spray hole 352. The downwardly focused spray hole 352, A rotary type centralized injection nozzle 350 provided with the rotary type central injection nozzle 350; A horizontal rotating means 360 for rotating the horizontal rotary pipe 330; And,
The rotary concentrated injection nozzle 350 is installed such that the downwardly focused injection hole 352 and the horizontal concentrated injection hole 353 are positioned below the ceiling half P,
The horizontal rotation means 360 includes a ring gear 361 coupled to the outer circumferential surface of the horizontal rotation pipe 330; A drive motor 362 vertically installed on the ceiling half P; A driving gear 364 fixed to the motor shaft 363 of the driving motor 362; And a transmission gear 365 engaged with the ring gear 361 and the drive gear 364,
The centralized injection device control means 400 controls the opening and closing control of the electromagnetic valve 320 and the operation of the drive motor (not shown) according to the output signal of the fire occurrence alarm portion / fire occurrence position instruction portion 209 of the fire signal processing device 200 A driving motor 362 for opening and closing the solenoid valve 320 according to a control command of the centralized injection device controller 410; And a drive motor driving unit (430) for sending a rotation drive signal to the fire alarm monitoring unit (420).

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