KR102221843B1 - Fire sensor having self- diagnosis - Google Patents

Abstract

The present invention provides a fire detector having a self-checking function. The fire detector having a self-checking function comprises: a fire sensor installed indoors; a control unit inputting fire information set by the fire sensor; and a determination unit transmitting a result of whether information on fire detection is output from the fire sensor, after the fire information is input, to the control unit. The fire information includes a temperature value of a flame and a concentration value of smoke when a fire occurs.

Description

Fire detector with self-inspection function {FIRE SENSOR HAVING SELF- DIAGNOSIS}

The present invention relates to a fire detector having a self-inspection function, and more particularly, by inputting fire simulation information set as a fire detector installed in a building to determine whether a fire is normally detected, and determining whether a fire sensor malfunctions in real time. It relates to a fire detector with a self-inspection function that can be checked.

Recently, as apartments have become skyscrapers and the security room of each building is operated as an integrated security room, new facilities such as the adoption of an R-type reception panel, addition of ventilation facilities, and sprinkler facilities are being installed. Strict management is being carried out.

On the other hand, currently commercially available or patented fire-related detectors are developed and used in various types according to their functions. In particular, the detector adopted in the R-type receiver has a self-recognition (Address) function in conjunction with a repeater, but high cost is required because it is a 4-port type and requires a 4-core shield cable. The detector used in the P-type receiver does not have an addressable function. Therefore, P-type detectors have the hassle of checking each medium for fault detection, and it is not possible to determine the exact location of the fire. In particular, when heat detectors such as differential type (spot) apply heat, smoke detectors send smoke to the detector. It should be checked at the receiver as it is generated.

In addition, conventional addressable detectors receive signals from sensors and transmit and receive signals using two dedicated signal lines, and DC power supplies power through separate two-stranded wires, and the frequency of use is specified. However, since it adopts a slightly higher frequency instead of a low frequency, it is inevitable to use a shielded cable to prevent electromagnetic deviation or high frequency interference during the transmission and reception process. For this reason, there is a significant disadvantage that cannot be applied to the existing P-type automated material detection facility installed with two-stranded general cables (IV, HIV). A fire detection device employing an R-type receiver that compensates for these shortcomings has been developed and presented as Korean Patent Publication No. 10-2013-0032162 (hereinafter, referred to as'prior patent').

The fire detection device of the prior patent is configured to perform both power supply and two-way communication functions using a two-wire DC power supply line as shown in FIG. 1, so that various types of wires can be used, and thus an existing building It can be applied to and shows the advantage of reducing the cost of new construction and maintenance. In addition, since two-way communication is performed using a DC power supply line, it is possible to check whether a detection device has failed.

However, in the fire detection device of the prior art, there is a problem in that it is not possible to check whether a malfunction or malfunction of various sensors installed in the detection device is performed. That is, in the conventional fire detection device, it is possible to check whether the detection device has failed depending on whether a communication signal is made between the detection device and the receiver, but the sensors constituting the detection device (heat detection sensor, smoke detection sensor, flame detection) Sensor, etc.) There is a problem of not being able to check whether there is a failure or malfunction of itself.

In order to solve this problem, conventionally, it was attempted to solve this problem by testing the sensor by generating smoke that can simulate a fire situation in the sensor device itself, but the failure of the smoke-generating device and the smoke generation concentration are constantly controlled. Failure to do so causes an error in the test itself, and in the event of a sensor failure, there is a problem in that it cannot be replaced immediately, so in the event of a fire, it is not possible to respond immediately.

Korean Patent Registration No. 10-0660155 (2006.12.14)

The present invention has been devised to solve the above-described problems, and the object of the present invention is as follows.

First, it is possible to check whether a fire sensor malfunctions in real time by determining whether a fire is normally detected by inputting fire simulation information set by a fire detector installed in a building.

Second, the fire information generated within a certain radius is received in real time, and the received fire information is applied to the fire sensor as a test target to determine whether or not the fire corresponding to the actual situation can be detected.

Third, when the fire sensor is malfunctioning or defective, a number of sensors installed in the sensor bracket rotate so that the normal sensor is connected to the connection terminal, so that the sensor replacement can be accomplished in real time.

In order to achieve the above objects, the present invention provides a fire detector having a self-check function.

The fire detector having the self-check function includes a fire sensor installed indoors;

A control unit for inputting fire information set by the fire sensor;

Including; after the fire information is input, a determination unit that transmits a result of whether information on fire detection is output from the fire sensor to the control unit;

The above fire information,

In the event of a fire, the temperature value of the flame and the concentration value of the smoke are included.

Here, the control unit,

Including an optional part,

The selection unit includes a manual mode, an actual mode, and a real-time mode,

When the manual mode is selected by the selection unit, the fire information is variably set through a separate input device,

When the actual mode is selected by the selection unit, the temperature value of the flame and the concentration value of the smoke that are the lowest among the range of the flame temperature and the concentration value of the smoke included in the previously stored existing fire information are displayed. Set it as fire information,

When the real-time mode is selected, the control unit receives fire information of another building detected from a fire sensor installed in another building within a certain radius through a wireless communication method,

It is preferable to set the received other fire information as the fire information.

And the determination unit,

When information on fire detection is not output from the fire sensor, the fire sensor is determined as a defective sensor,

Selecting other fire sensors located within a radius set from the defective sensor,

Selecting normal fire sensors for outputting information on the fire detection among the other fire sensors,

Average processing of output information output from the normal fire sensors,

It is preferable to set the average-processed output information to be replaced with the output information of the defective sensor in the control unit for a set time.

Moreover, the fire sensor comprises a plurality,

Brackets are provided at certain locations in the building,

A rotation motor having a rotation shaft is installed at the bottom of the bracket,

A circular rotation fixing member having a center fixed at the end of the rotation shaft is disposed,

The fire sensors constituting the plurality are installed at intervals on the circumference of the rotation fixing member,

A support bracket extending to the lower end of the bracket is installed,

A first connection terminal electrically connected to the control unit is installed at an end of the support bracket,

Each of the plurality of fire sensors is provided with a second connection terminal connected to the first connection terminal as it rotates,

The control unit,

When the defective sensor is generated in the plurality of fire sensors, the rotation shaft of the rotary motor is rotated so that a second connection terminal of any one of the plurality of fire sensors excluding the defective sensor is connected to the first connection terminal.

In addition, in the bracket,

A cover surrounding the circumference of the rotation fixing member is installed,

The cover,

It is connected with a heat-resistant tube that is connected to the outside,

A fan is installed on the tube,

In the cover,

A sensor module for measuring the temperature and humidity of the inner space of the cover is installed,

The control unit,

The fan is driven so that the measured temperature and humidity reach a preset reference temperature and reference humidity to ventilate the inner space of the cover.

As described above, the present invention determines whether or not a fire is normally detected by inputting fire simulation information set as a fire detector installed in a building, so that a malfunction of the fire sensor can be checked in real time,

The fire information that occurs within a certain radius is received in real time, and the received fire information is applied to the fire sensor to be tested to determine whether or not the fire corresponding to the actual situation can be detected.

When the fire sensor is malfunctioning or defective, a number of sensors installed in the sensor bracket rotate so that the normal sensor is connected to the connection terminal, so that sensor replacement can be accomplished in real time.

1 is a diagram showing the configuration of a fire detector having a self-inspection function.
2 is a flowchart showing a flow of a selection unit according to the present invention.
3 is a view showing the configuration of the fire sensor of the present invention.
4 is a view showing a rotation fixing member.
5 is a view showing an example in which a fire sensor according to the present invention is installed on a bracket and is surrounded by a cover.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those of ordinary skill in the art may easily implement the present invention.

The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are attached to the same or similar components throughout the specification.

Hereinafter, it means that an arbitrary configuration is provided or disposed on the "top (or bottom)" of the base material or the "top (or bottom)" of the base material is provided or disposed in contact with the top (or bottom) of the base material. Means that.

In addition, it is not limited to not including other configurations between the base material and any configurations provided or disposed on (or under) the base material.

The following describes the present invention with reference to the accompanying drawings.

1 is a diagram showing the configuration of a fire detector having a self-inspection function.

Referring to FIG. 1, the fire detector having a self-check function includes a fire sensor 100 installed indoors, a control unit 200 for inputting set fire information with the fire sensor 100, and the fire information. After being input, it has a determination unit 300 that transmits a result of whether information on fire detection is output from the fire sensor 100 to the control unit 200.

The fire information includes a flame temperature value and a smoke concentration value when a fire occurs.

Here, the control unit 200 includes a selection unit 400.

2 is a flowchart showing a flow of a selection unit according to the present invention.

The selection unit 400 includes a manual mode, an actual mode, and a real-time mode.

When the manual mode is selected by the selection unit 400, the fire information is variably set through a separate input device (not shown).

When the actual mode is selected by the selection unit 400, the temperature value of the flame and the concentration of the smoke that are the lowest among the range of the temperature value of the flame included in the previously stored existing fire information and the range of the concentration value of the smoke Set the value to the above fire information.

When the real-time mode is selected, the control unit 200 receives the fire information of other buildings detected from a fire sensor installed in another building within a certain radius through a wireless communication method, and transmits the received other fire information. Set with fire information.

In addition, when information on fire detection is not output from the fire sensor 100, the determination unit 300 determines the fire sensor 100 as a defective sensor.

The determination unit 300 selects other fire sensors located within a radius set from the defective sensor.

The determination unit 300 selects normal fire sensors for outputting information on the fire detection among the other fire sensors.

The determination unit 300 averages the output information output from the normal fire sensors.

The determination unit 300 sets the average-processed output information to be replaced with the output information of the defective sensor in the control unit 200 for a set time.

3 is a view showing the configuration of the fire sensor of the present invention, Figure 4 is a view showing a rotation fixing member.

Furthermore, referring to FIGS. 3 and 4, the fire sensor 100 constitutes a plurality.

A bracket 510 is provided at a certain position of the building.

A rotation motor 520 having a rotation shaft 521 is installed at the lower end of the bracket 510.

A circular rotation fixing member 530 having a center fixed at an end of the rotation shaft 521 is disposed.

The fire sensors 100 constituting the plurality are installed at intervals on the circumference of the rotation fixing member 530.

A support bracket 511 extending to the lower end of the bracket 510 is installed.

A first connection terminal 540 electrically connected to the control unit 200 is installed at an end of the support bracket 511.

Each of the plurality of fire sensors 100 is provided with a second connection terminal 110 connected to the first connection terminal 540 as it rotates.

When the defective sensor is generated in the plurality of fire sensors 100, the control unit 200 comprises the second connection terminal 110 of any one of the plurality of fire sensors 100 excluding the defective sensor. The rotation shaft 521 of the rotation motor 520 is rotated to be connected to the first connection terminal 540.

5 is a view showing an example in which a fire sensor according to the present invention is installed on a bracket and is surrounded by a cover.

Referring to FIG. 5, a cover 570 surrounding the circumference of the rotation fixing member 530 is installed on the bracket 510.

The cover 570 is connected to a heat-resistant tube 580 connected to the outside.

A fan 590 is installed on the tube 580.

A sensor module 600 for measuring the temperature and humidity of the inner space of the cover 570 is installed on the cover 570.

The control unit 200 drives the fan 590 so that the measured temperature and humidity reach a preset reference temperature and reference humidity to ventilate the inner space of the cover 570.

Accordingly, the present invention determines whether or not a fire is normally detected by inputting fire simulation information set as a fire detector installed in a building, so that a malfunction of the fire sensor can be confirmed in real time.

In addition, according to the present invention, fire information generated within a certain radius is received in real time, and the received fire information is applied to a fire sensor as a test target to determine whether a fire corresponding to an actual situation can be detected.

In addition, the present invention makes it possible to perform sensor replacement in real time by rotating a normal sensor to be connected to a connection terminal in a plurality of sensors installed in a sensor bracket when a fire sensor is malfunctioning or defective.

The present invention is not limited to the specific preferred embodiments described above, and any person having ordinary knowledge in the technical field to which the design belongs without departing from the gist of the present invention claimed in the claims can implement various modifications. Of course, such changes are intended to be within the scope of the description of the claims.

100: fire sensor
200: control unit
300: judgment unit

Claims (3)

Fire sensors installed indoors;
A control unit for inputting fire information set by the fire sensor;
Including; after the fire information is input, a determination unit that transmits a result of whether information on fire detection is output from the fire sensor to the control unit;
The above fire information,
In the event of a fire, the temperature value of the flame and the concentration value of the smoke are included,
The control unit,
Including an optional part,
The selection unit includes a manual mode, an actual mode, and a real-time mode,
When the manual mode is selected by the selection unit, the fire information is variably set through a separate input device,
When the actual mode is selected by the selection unit, the temperature value of the flame and the concentration value of the smoke that are the lowest among the range of the temperature value of the flame included in the previously stored existing fire information and the range of the concentration value of the smoke are displayed. Set it as fire information,
When the real-time mode is selected, the control unit receives fire information of another building detected from a fire sensor installed in another building within a certain radius through a wireless communication method,
Setting the received other fire information as the fire information,
Fire detector with self-check function.
delete The method of claim 1,
The determination unit,
When information on fire detection is not output from the fire sensor, the fire sensor is determined as a defective sensor,
Selecting other fire sensors located within a radius set from the defective sensor,
Selecting normal fire sensors for outputting information on the fire detection among the other fire sensors,
Average processing of output information output from the normal fire sensors,
Setting the average-processed output information to the controller to replace the output information of the defective sensor for a set time,
Fire detector with self-check function.

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