KR102008618B1 - Line resistance meter of fire-prevention facilities - Google Patents

Abstract

The present invention relates to a line resistance measuring device of a fire protection facility, which is a line resistance measuring device installed on a line connected between fire protection facilities installed in a receiver of the fire protection facilities and a boundary area. The line resistance measuring device comprises: a switch button connecting a relay to a line on a boundary area side; a resistance measuring unit measuring resistance of the line on the boundary area side; a display unit displaying the resistance measured by the resistance measuring unit; and a control unit controlling the relay to be operated to measure the resistance so as to be connected with the line of the boundary area side for a predetermined time and to be disconnected when the switch button is pressed.

Description

Line resistance meter of fire-prevention facilities

The present invention relates to a line resistance measuring device of the fire fighting equipment.

Recently, the demand for the development of a new fire protection system has been increased due to the change in the construction environment such as the high-rise and large-scale buildings and the appearance of large-scale complex underground spaces. In addition, as the development and technology of the fire fighting industry progress, the fire fighting environment is continuously changing rapidly, with the development and flow of new machinery and equipment related to fire fighting.

In addition, in the case of new construction by changing the interior interior after the fire equipment is installed in the building, the communication lines of the fire fighting equipment are often additionally wired. The lines of fire-fighting equipment are routed to form one series circuit at each boundary area of the building, and additional wiring breaks the middle of the line and connects additional lines.

By the way, one communication line should be made less than 1.5km in length, and if it exceeds 1.5km, there is a case in which an alarm signal or an automatic fire extinguishing system malfunctions due to an erroneous signal generated between the sensor and the receiver. Therefore, it is necessary to check the length of the currently installed line before performing additional wiring work.

However, the tracks of fire-fighting equipment should be connected at all times in case of fire. A typical resistance measuring instrument must cut a specific point of a line forming a closed circuit to measure the resistance of the line. Therefore, a general resistance meter could not be connected to measure the resistance of the line through which the signal is always transmitted.

Korean Patent Publication No. 10-2015-0141065 "Fire fighting system check system and method"

An object of the present invention is to provide a line resistance measuring instrument that can easily determine the length of the track by easily measuring the resistance of the line that is always connected to the fire fighting equipment.

The line resistance measuring device of the fire-fighting equipment of the present invention for achieving the above object is a line resistance measuring instrument installed on a line connected between the fire-fighting equipment installed in the receiver and the boundary area of the fire-fighting equipment, the line resistance measuring device, A relay selectively connected to the line on the border zone side, a switch button for connecting the relay to the line on the border zone side, a resistance measurement unit for measuring resistance of the line on the border zone side, and a resistance measurement unit And a control unit for controlling the resistance by measuring the resistance by operating the relay to be disconnected after a predetermined time when the switch button is pressed and the boundary area side line when the switch button is pressed.

Preferably, the controller controls the measured resistance value to be maintained in a digitally displayed state on the display unit.

It is preferable that the predetermined time for which the relay is connected to the border line side line is 0.1 to 0.4 seconds.

It is preferable that the line resistance measuring device warns that the proper line length is exceeded on the display unit when the measured resistance value exceeds 50Ω.

The line resistance measuring instrument is preferably installed one by one between the receiver and the plurality of boundary zones.

According to the track resistance measuring device of the fire-fighting equipment of the present invention described above, the length of the track can be determined by easily measuring the resistance of the track that is always connected to the fire-fighting equipment.

In addition, since the line resistance meter breaks the line for only a very short time and measures the resistance, the receiver does not even recognize the line as disconnected during the measurement and does not affect the transmission of the fire signal at all.

In addition, the line resistance measuring instrument may maintain a state in which the measured resistance value is displayed on the display unit even when the line is disconnected from the line.

Figure 1 is a schematic diagram showing that the line resistance measuring instrument according to an embodiment of the present invention is connected to the line of the fire extinguishing equipment.
2 is a block diagram showing the configuration of the line resistance measuring instrument.
3 is a schematic diagram illustrating a state in which a line is connected to a line resistance meter by operating a relay in FIG. 1.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a schematic diagram showing that the line resistance measuring instrument according to an embodiment of the present invention is connected to the line of the fire extinguishing equipment.

In general, fire fighting equipment installed in a large building includes a receiver 100 and a detector, a transmitter, an alarm, a fire extinguishing system and the like installed in the boundary area.

Automated re-detection equipment not only fires but also tells you where the fire came from. The fire occurrence point lights up the earth indicator at the receiver or displays it in letters on the LCD display, and the area covered by this earth indicator or one letter can be called a border zone.

'Border area' refers to the area where fire signal can be transmitted and the signal can be received and effectively controlled. In other words, the boundary area means the area in which one circuit of the automated detection system can effectively detect the occurrence of fire.

If the boundary area is subdivided, the fire generating area can be known exactly. But to do so requires a lot of lines and globe lights. Therefore, the law stipulates the extent of the boundary area so that the location of the fire can be easily identified and economically burdened.

In FIG. 1, various fire fighting facilities are installed in one boundary area B1, and the fire fighting facilities and the receiver 100 are connected by a communication line to form a closed circuit.

Examples of fire fighting equipment include a repeater 110, a detector 120, a transmitter unit 130, a visual alarm 140, an automatic fire extinguishing facility 150, and the like.

First, the receiver 100 may be directly connected by a wire such as a detector or a transmitter, or connected with a repeater interposed therebetween, and may display its position when the detector, repeater, or transmitter operates.

The receiver 100 may be classified into a P type (proprietary type), R type (record type), M type (municipal type), GP type, GR type. P-type and R-type receivers have advantages and disadvantages corresponding to each other. P-type receivers are advantageous for small apartments, and R-type receivers are advantageous for skyscrapers or large apartments. A repeater is not connected to the P-type receiver and a repeater is required for the R-type receiver. However, in the present invention, the type of the receiver 100 is not limited to the R type receiver.

The receiver 100 may be equipped with a main bell, and may be used in connection with various functional devices required for fire fighting, such as a fire pump starting device, an auxiliary receiver, an emergency alarm device, a fire damper, a disaster prevention notification receiver, and the like.

The repeater 110 receives a signal from a detector or a transmitter and transmits the signal to a receiver, and receives and relays a control signal of a facility for disaster prevention. If the receiver 100 is a P-type receiver, there may be no repeater.

Repeater 110 may be installed one or more per boundary area.

Detector 120 is a sensor that automatically detects heat, smoke, etc. generated by the fire and sends the signal to the receiver, the type includes a heat detector, smoke detector, composite detector, flame detector and the like.

A plurality of detectors 120 may be arranged in one boundary area at predetermined intervals, and multiple detectors of different types may be installed. In addition, the plurality of detectors may be connected in parallel to each other on one line.

The transmitter unit 130 is a fire detector manually fires a fire signal, the person pressing when the fire occurs, the transmitter 132, the earth alarm bell 134 that is activated when the transmitter or when the automatic re-detection signal is received, the fire location It may include a position indicator 136 to indicate to identify.

The visual alarm 140 is a device that alerts by strongly blinking the lamp for the hearing impaired who do not hear the alarm.

Automatic fire extinguishing facility 150 is installed so that the fire extinguishing system is automatically operated when a fire detection signal is received automatically or manually.

Examples of the automatic fire extinguishing facility 150 include an automatic fire extinguisher, an indoor fire hydrant, a sprinkler, a drencher, a gas fire extinguishing device, and the like.

Automatic fire extinguishers are fire extinguishers that automatically extinguish or extinguish extinguishing agents by fire or heat in case of fire.

Indoor fire hydrant is a fire extinguishing system installed in the building so that the relevant person, self-defense fire fighter or regular resident of the fire object can quickly extinguish (fire extinguish) at the early stage of fire ignition. Piping, opening and closing valve, indoor fire extinguisher (indoor fire extinguishing drain, pipe, hose, etc.) and the like. In case of fire, the valve is automatically opened and can be used by opening the angle valve before fire hydrant or by operating the fire pump start type switch.

The sprinkler is a facility in which the metal of the sprinkler head attached to the upper part of the building, that is, the ceiling or the wall is melted by the heat in the event of a fire, and the pressurized water is sprayed from the head to the entire ignition point. As soon as the sprinkler is activated, fire notification and extinguishing can be carried out automatically at the beginning of the ignition.

The drencher is to be installed in the case where a fire door cannot be installed in the opening or in the presence of a fire door even if there is a fire door. There are a method of preventing combustion by protecting the opening and a method of preventing combustion from the outside by covering the entire exterior of the building with a water film. The drencher head is open and basically the same as a sprinkler installation.

A gas fire extinguishing system is a fire extinguishing system that extinguish a fire by releasing an adaptive gas extinguishing agent into a room. Digestive gases include carbon dioxide and halogen compounds. Fire extinguishing equipment may consist of storage containers, starting containers, selector valves, starting devices, release indicators, sirens, detectors and the like.

One or more of the above facilities installed in one boundary zone B1 may be absent, a plurality may be installed, and another type of fire fighting equipment may be further installed.

In FIG. 1, the additional wiring in the line connected to the first boundary zone B1 for installing the fire fighting facilities in the second boundary zone B2 is illustrated by dotted lines. That is, it may be additionally wired by disconnecting between two points P1 and P2 of the track close to the first boundary zone B1 and connecting the lines connected to the fire fighting facilities of the second boundary zone B2.

In particular, in the case of renovating the interior of a building, additional wiring may be performed using an existing line. Additional wiring is not always required between multiple boundary spaces, but additional wiring may be provided for the installation of additional fire protection equipment within a single boundary space.

However, in the case of such additional wiring, the length of the line that constitutes one closed circuit in which the receiver and the fire fighting equipment are connected in series is limited to 1.2 to 1.5 km. If the length of the line exceeds 1.5km, the signal transmitted and received between the receiver and the detector may cause an error in the fire fighting equipment. For example, if a fire signal is generated even though a fire does not occur, a large amount of damage occurs when the sprinkler is operated or the extinguishing gas is released.

Therefore, before the additional wiring as described above, it is necessary to measure the resistance of the existing line to confirm that the length of the line is within 1.2 ~ 1.5km and there is room for additional wiring.

To this end, the line resistance measuring instrument 200 of the present invention is installed near the receiver 100 on a line connecting the receiver 100 and the fire fighting facilities.

As shown in FIG. 2, the line resistance meter 200 includes a relay 210 selectively connected to a line on the border zone, a switch button 220 to connect the relay to a line on the border zone, and a border zone. It may include a resistance measuring unit 240 for measuring the resistance of the side line, and a display unit 250 for displaying the resistance measured by the resistance measuring unit.

The relay 210 is a kind of electric switch that normally connects the line between the receiver 100 and the detector 120 and connects the line of the detector 120 to the line resistance meter 200 when an operation signal is input.

The switch button 220 is provided on the outer surface of the line resistance measuring instrument 200 to operate the relay 210 when pressed by the user. The switch button 220 may be in the form of a push button, but is not limited thereto and may be formed in another form such as a touch button.

The resistance measuring unit 240 is an ohmmeter connected in parallel in a state where power is not applied to the line in order to measure the resistance of the line on the boundary zone side. Thus, the resistance measurement unit 240 may measure the resistance of the boundary zone side line while the relay 210 is turned on and the boundary zone side line and the line resistance meter 200 are connected.

The display unit 250 displays the resistance measured by the resistance measuring unit 240. In general, the ohmmeter loses the indication of the measured resistance when the resistance measurement is disconnected. However, in the present invention, the display unit 250 allows the measured resistance value to be maintained in the digital display state.

The line resistance measuring apparatus 200 of the present invention further includes a controller 230 for controlling the relay 210, the resistance measuring unit 240, and the display unit 250.

When the switch button 220 is pressed, the controller 230 operates the relay 210 to be disconnected from the line of the boundary zone for a predetermined time and then disconnects, and during this time, the resistance measuring unit 240 controls to measure the resistance. In addition, the controller 230 controls the display unit 250 to maintain a state where the measured resistance value is displayed for a predetermined time or more.

Preferably, the predetermined time for which the relay 210 is connected to the border zone side line is 0.1 to 0.4 seconds. More preferably, the relay 210 may be controlled to be turned on and off for only 0.2 to 0.3 seconds.

3 illustrates a state in which the relay 210 is turned on and connected to a line on the border zone side. In this case, since the line between the receiver 100 and the detector 120 is only disconnected for a very short time despite the temporary disconnection, the receiver 100 does not even recognize the disconnection and the receiver 100 and the detector 120 do not recognize the disconnection. There is no effect on the transmission and reception of signals between the channels.

It is preferable that the line resistance measuring device 200 warn that the appropriate line length is exceeded on the display unit when the measured resistance value exceeds 50Ω. Since the resistance of the line is proportional to the length of the line, if the resistance value is 50 Ω, it can be determined that the length of the line corresponds to about 1.2 to 1.5 km. By outputting a visual or audio message to the display when the measured resistance exceeds 50Ω, it is possible to reliably prevent the user from further wiring and the length of the line exceeding an appropriate length.

The line resistance measuring device 200 is preferably installed one by one between the receiver 100 and the plurality of boundary zones.

As illustrated in FIG. 1, an Nth line resistance measuring instrument is installed on a line connected between the fire fighting equipment BN of the boundary zone N and the receiver 100. That is, when the boundary zone is divided into N and the lines are wired between each boundary zone and the receiver 100, the line resistance measuring instrument of the present invention may be installed one for each line. Therefore, by measuring the line resistance value by pressing the switch button of the line resistance meter connected to the line to be wired additionally, it is very easy to know the possibility of additional wiring to the line.

Although the preferred embodiment of the present invention has been described above, the scope of the present invention is not limited only to this specific embodiment, and those skilled in the art are appropriately within the scope described in the claims of the present invention. Changes will be possible.

100: receiver 110: repeater
120: detector 130: transmitter unit
140: visual alarm 150: automatic fire extinguishing equipment
200: line resistance meter 210: relay
220: switch button 230: control unit
240: resistance measurement unit 250: display unit

Claims (5)

It is a line resistance meter installed on the line connected between the fire protection receiver and the fire protection facilities installed in the boundary area.
The line resistance meter,
A relay connected to a line between the receiver and the border zone to selectively connect a line resistance meter;
A switch button for operating the relay to connect the line resistance meter to the line on the border zone;
A resistance measuring unit measuring resistance of the line on the border zone;
A display unit displaying the resistance measured by the resistance measuring unit;
When the switch button is pressed, the relay is operated so that the line resistance measuring instrument is disconnected from the line for the boundary area for 0.1 to 0.4 seconds and then disconnected, and the resistance measuring unit measures the resistance during the connection time. And a control unit for controlling the display unit to maintain the digitally displayed state. delete delete The method of claim 1,
The line resistance measuring instrument of claim 2, wherein if the measured resistance value exceeds 50 Ω, the display unit warns that an appropriate line length is exceeded. The method of claim 4, wherein
The line resistance measuring device is a line resistance measuring device of the fire protection equipment, characterized in that each one is installed between the receiver and a plurality of boundary zones.

Images