KR101403042B1 - A system for monitoring a fire - Google Patents

Abstract

The present invention relates to a fire prevention system capable of detecting an abnormality of a power line to reduce a fire caused by an electric line, an indoor sensing unit for sensing an abnormal signal in a building, And an abnormal signal detection unit for detecting a type and a generated position of the first monitoring area and a second monitoring area for detecting smoke and heat generated in the respective monitoring areas, Each of the first to nth monitoring regions is provided with an indoor sensing unit for each of the first to nth monitoring regions and the first to nth monitoring regions, Monitoring area having a monitoring area to an nth load monitoring area, and a monitoring area having a monitoring area for monitoring the first load monitoring area to the nth load monitoring Supplying electric power to the station, and having minute through the power line of the first load monitoring area to n-th detected first power line sensor to the n power lines to sense the load on the load monitoring areas, each unit including all.

Description

A system for monitoring a fire

FIELD OF THE INVENTION The present invention relates to a fire prevention system, and more particularly, to a fire prevention system capable of detecting an abnormality of a power line to reduce a fire caused by an electric line.

Generally, a fire receiver is installed in a place where a person is always working to detect a fire, warn a fire when a fire is detected, and perform an operation (such as operation of a fire extinguisher such as a sprinkler or a hydrant) Equipment.

These fire receivers mainly include a P-type fire receiver, which is a contact type based on a one-to-one signal line, and an R-type fire receiver, which alerts a fire by a circuit specific signaling method by a multiple communication transmission method.

Here, the P-type receiver is suitable for small-sized living spaces, small buildings, apartments, small-scale factories, and the like, which are less expensive than R-type.

The R-type receiver is suitable for high-rise buildings, large apartment buildings, and large-scale factories where signal strength is assured and circuit expansion and installation is easy, resulting in a significant increase in voltage drop and trunk line number.

P-type fire receivers or R-type fire receivers all detect fire through commercial fire detectors. In this case, the conventional fire receiving system is composed of several fire receivers connected in series and one fire detector is connected to the fire receiver at one point to make an alarm and operate the disaster prevention device.

This structure allows the fire to be detected after a fire or smoke is generated and the scale of the fire spreads to a perceivable fire on a wall or ceiling fire detector.

Recently, as the number of buildings is increasing and the size of buildings is increasing, the number of electric power equipment for precise control due to advanced commercialization is increasing due to the increase of electric power facilities. Especially, in a case where a plurality of buildings are spaced apart from each other by a certain distance, a plurality of electric power facilities are installed in each building, and a large electric power is supplied to a plurality of electric power facilities at a time through a distribution board or water / switchboard, The distribution panel and the water / switchboard have a large number of fire risk factors due to the burning of wiring and the like. When a fire occurs in the power distributing device such as the distribution panel or the water / switchboard, the power distributing device and the wiring work are performed again. Therefore, there arises a problem such as a large expenditure of the construction cost and a delay in the power supply.

The conventional fire detection system includes a fire prevention system including an automatic fire evacuation function of Korean Registered Utility Model No. 20-0243481, a fire prevention system of Korean Patent Laid-Open Publication No. 10-2012-0037640 And a method "

The conventional technique as described above has a problem in that a fire generated by a wire in a building can not be prevented in advance.

SUMMARY OF THE INVENTION The present invention has been developed in order to overcome the above-mentioned problems of the prior art, and provides a fire prevention system capable of detecting an abnormality of a power line and detecting a position of a corresponding power line where an abnormality occurs, It has its purpose.

In order to achieve the above object, according to the present invention, there is provided a monitoring system comprising an indoor sensing unit for sensing an abnormal signal in a building, a monitoring server for receiving an abnormal signal of the power line and detecting an abnormal signal type, Wherein each of the first to nth monitoring regions is divided into a first to nth monitoring regions, and each of the first to nth monitoring regions includes an indoor sensing portion for sensing smoke, heat, and gas generated in the respective monitoring regions, A monitoring area having a first load monitoring area to an nth load monitoring area in each of the first to nth monitoring areas so as to detect an abnormality of a wire wired to the first to nth monitoring areas, And supplies power to the first load monitoring region through the nth load monitoring region through a power line, Sensing a load of the surveillance region and each of the first power line to n-th detector provides a fire protection system which includes all of the minutes comprising a power line detection unit.

Also, the present invention provides a fire prevention system including an abnormal signal detecting unit for detecting an abnormal signal of an arc current, an overcurrent, and a leakage current according to a signal transmitted from the first power line sensing unit to the nth power line sensing unit.

The present invention also relates to a method for detecting a leakage current of a low-frequency component of a wire, which detects an overcurrent, a leakage current, and an arc current through waveforms of currents and currents applied to the wires, A current detector for detecting a waveform of a current that is distorted when an arc of the electric wire is generated; and a power breaker for blocking power supplied to the first to nth monitoring regions to the nth monitoring region .

According to the fire prevention system according to the present invention, the distribution board detects an abnormality of the power line by sensing the abnormality of the power line installed inside the building through the waveform of the current, and detects the position of the corresponding power line where the abnormality occurs , There is an advantage that fire caused by a wire can be reduced.

1 is a block diagram illustrating a fire prevention system according to an embodiment of the present invention.
2 is a block diagram illustrating a power line sensing unit according to an embodiment of the present invention.
3 is a block diagram illustrating an arc sensing unit according to an embodiment of the present invention.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It must be interpreted in terms of meaning and concept.

Hereinafter, a fire prevention system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 3, the fire prevention system according to the present embodiment includes a monitoring server 100 for detecting a signal generated in a building, And a power dividing unit 300 for supplying power to each of the divided regions of the monitoring region 200. The power dividing unit 300 includes a power supply unit 300,

At this time, the fire prevention system according to the present embodiment divides the surveillance region 200 so that the surveillance region 200 corresponds to the number of branch lines of the power line wired by the power distributing unit 300.

The monitoring server 100 includes an indoor sensing unit 110 for sensing an abnormal signal generated in the monitoring area 200 and a plurality of power lines And an abnormal signal detector 120 for receiving an abnormal signal from the power divider 300 to sense an abnormality of the surveillance region 200 through a signal.

The monitoring area 200 is divided into a first monitoring area 201, a second monitoring area 202, a third monitoring area 203 and an nth monitoring area 204. The first monitoring area 201, And the indoor sensing units 205, 206, 207, and 208 are provided in the nth monitoring area 204, respectively. The indoor detectors 205, 206, 207 and 208 detect smoke, heat, gas and images generated in the first to nth monitoring regions 201 to 204, A gas sensing unit and an image sensing unit.

The smoke, heat, and gas sensing unit includes a smoke sensor, a thermal sensor, and a gas sensor for sensing smoke, heat, and gas generated in the first to nth monitoring regions 201 to 204 And detects abnormalities occurring in the first to nth monitoring regions 201 to 204 and transmits an abnormal signal to the indoor sensing unit 110. [

The image sensing unit captures images of the first to nth monitoring regions 201 to 204 and transmits them to the indoor sensing unit 110.

Each of the first to nth monitoring regions 201 to 204 may include a first load monitoring region 210, a second load monitoring region 220, a third load monitoring region 220, And an nth load monitoring area 240. The first load monitoring area 210 to the nth load monitoring area 240 are provided with power lines 300, And the wires are connected.

The power dividing unit 300 is connected to the first load monitoring region 210 through the nth load monitoring region 240 through respective power lines so as to supply currents to the first load monitoring region 210 to the nth load monitoring region 240, A first power line sensing unit 310 for supplying power to the load monitoring area 240 and sensing a load on the wires of the first load monitoring area 210 to the nth load monitoring area 240 through the power line, A second power line sensing unit 320, a third power line sensing unit 330, and an n th power line sensing unit 340.

The first power line sensing part 310 to the n th power line sensing part 340 are connected to the first load monitoring area 210 through the nth load monitoring area 240 via the waveforms of the current and the current A leakage current detector (311, 321, 331, 332) for detecting a minute leakage current of a low frequency component of the electric wires of the first load monitoring area (210) to the nth load monitoring area (240) so as to detect overcurrent, leakage current, A current waveform detection unit 313, 323, 333, 343 for detecting a waveform of a current which is distorted when an arc of the electric wire is generated, and a first load monitoring area 210 to an nth load monitoring area 240 (315, 425, 335, 345) and an arc detection unit (317, 327, 337, 347)

At this time, the leakage current detectors 311, 321, 331 and 341 can use ZCT (Zero Current Transformer) and the current waveform detector 120 can use CT (Current Transformer).

The leakage current detecting units 311, 321, 331, and 341 are provided with a ring-shaped iron core capable of detecting only low frequency components, and function to detect a minute current in units of [A] And then outputted to the arc current determination unit 317d of the arc detection units 317, 327, 337, and 347 to be described later.

The monitoring server 100 transmits monitoring data and an anomalous alarm to the indoor sensing unit 110 and the abnormal signal sensing unit 120 according to signals received from the monitoring area 200 and the distributing unit 300, To a central control server (not shown).

Referring again to FIG. 3, the arc sensing units 317, 327, 337, and 347 according to the present embodiment will be described in detail.

The arc detection units 317, 327, 337, and 347 are connected to a load current detection sensor 317a, an arc characteristic filter unit 317a, A first amplifier 317b, a first amplifier 317c, and an arc current determination unit 317d.

In addition, the fire prevention system according to the present invention further includes a leakage current detector 50 for detecting a leakage current of the power line and a second amplifier 60 for amplifying a signal of the leakage current detector 50.

In addition, the fire prevention system according to the present invention further includes a circuit breaker 1 for interrupting a current flowing to the hot line, and the circuit breaker 1 is controlled by the arc current determination unit 317d .

The load current detection sensor 10 is provided on the electric wire to sense a change amount of a current flowing through the electric wire, and outputs a current sensing signal to the arc characteristic filter unit 317b. The load current detection sensor 10 according to the present embodiment can use a current transformer (CT) for a meter and detects a current water wave generated due to a short circuit of the electric wire, deterioration of insulation coating, insulation breakdown, do.

The arc characteristic filter unit 317b removes the high frequency signal of the voltage from the signal output from the load current detection sensor 10 and detects only the frequency signal of the current and outputs it to the first amplifier 30.

The first amplifier 30 amplifies the current frequency signal filtered by the arc characteristic filter unit 317b and outputs it to the arc current determination unit 317d.

The arc current determination unit 317d converts the frequency signal of the current output from the first amplifier 30 to determine whether a current frequency smaller than the reference current frequency (60 Hz) of the electric wire is generated . At this time, the arc current determination unit 317d performs Fast Fourier Transform (FFT) on the reference current frequency so as to detect a parallel arc among the noise generated together with the reference current frequency.

That is, the arc current determination unit 317d converts the current frequency signal amplified and output from the first amplifier 30 from the time domain to the frequency domain.

Then, the parallel arc current, which is the load noise generated together with the reference current frequency, appears more clearly in the frequency domain than in the time domain, and the parallel arc current frequency appearing at this time is smaller than the reference current frequency.

When the arc current frequency determining unit 317d determines that the arc current frequency is smaller than the reference current frequency, the arc current determining unit 317d determines that the arc current frequency is a parallel arc current, .

The arc sensing units 317, 327, 337 and 347 are provided in the first power line sensing unit 310 to the nth power line sensing unit 340, It detects parallel arcs.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is understandable. Accordingly, the true scope of the present invention should be determined by the following claims.

100: Surveillance server 200: Surveillance area
300: Power supply unit 310: First power line sensing unit
320: second power line sensing unit 330: third power line sensing unit
340: n power line sensing unit

Claims (3)

A monitoring server (100) comprising an indoor sensing unit for sensing an abnormal signal in a building, and an abnormal signal detecting unit for receiving an abnormal signal of the power line and detecting a type and a generated position of the abnormal signal;
Wherein each of the first to nth monitoring regions is divided into a first to nth monitoring regions, and each of the first to nth monitoring regions includes an indoor sensing portion for sensing smoke, heat, and gas generated in the respective monitoring regions, A monitoring area (200) having a first load monitoring area to an nth load monitoring area, respectively, in each of the first to nth monitoring areas so as to detect an abnormality of a wire wired to the first to nth monitoring areas, ; And
A first power line sensing part for supplying power to the first load monitoring area to the nth load monitoring area through respective power lines and for sensing a load of the first load monitoring area to the nth load monitoring area through the power line, And a power divider (300) having an n-th power line sensing unit,
The first power line sensing part to the n th power line sensing part may include:
A current waveform detector for detecting a waveform of a current which is distorted when an arc of the electric wire is generated; and a current detector for detecting an electric current supplied to the first to n < th > A power interrupter for interrupting power,
And an arc detection unit for detecting a parallel arc generated in the electric wire of the power line,
The arc detection unit includes:
A load current detecting sensor for detecting a change amount of a current flowing in the electric wire of the power line;
An arc characteristic filter unit for removing a high frequency signal of a voltage from a signal output from the load current detection sensor and detecting only a frequency signal of a current;
An amplifier for amplifying the current frequency signal filtered by the arc characteristic filter unit; And
A current frequency signal output from the amplifier is converted from a time domain to a frequency domain through an FFT (Fast Fourier Transform), and when an arc current frequency smaller than a reference current frequency occurs, an arc And a current judging unit for judging whether or not the fire has occurred. The method according to claim 1,
Wherein the abnormal signal detection unit detects an abnormal signal of an arc current, an overcurrent, and a leakage current according to a signal transmitted from the first power line sensing unit to the n th power line sensing unit. delete

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