KR20230144923A - Method for preventing unwanted fire alarm and system thereof - Google Patents

Abstract

A method for preventing non-fire alarms is disclosed. According to one aspect of the present invention, in the method of preventing false alarms using a P-type receiver including a detector and connected to an electric circuit installed in a plurality of districts, the receiver receives the measured voltage of the electric circuit from the P-type receiver in real time. receiving, a determining unit comparing the measured voltage with a plurality of preset voltage ranges to determine the state of the electric circuit including a normal state and a fire detection state, and if the recovery unit determines that the fire is detected, the P-type receiver is A non-fire alarm comprising a step of restoring, and a step of determining that a non-fire alarm has occurred when the electric circuit is determined to be in a normal state by comparing the measured voltage after a set time has elapsed from the recovery point of the P-type receiver to a plurality of voltage ranges. A prevention method is provided.

Description

Unwanted fire alarm prevention method and system {METHOD FOR PREVENTING UNWANTED FIRE ALARM AND SYSTEM THEREOF}

The present invention relates to a method and system for preventing false alarms.

Despite continuous national investment in the field of firefighting, such as converting firefighters to national positions, increasing firefighting manpower, and dispatching local fire officials in the event of a fire, casualties from fires are increasing.

The main reason for this is the delay in evacuation in the event of an actual fire due to the decline in reliability of fire alarms. This is believed to be due to the frequent occurrence of non-fire alarms, which are fire alarms in cases other than fire.

The rate of firefighting dispatch due to such non-fire reports has been steadily increasing over the past 10 years, and as a result, firefighting power is wasted and unnecessary social costs are increasing.

Therefore, it can be said that there is a high need to develop a method that can effectively prevent non-fire alarms to prevent increased casualties and unnecessary waste of firefighting power due to the decline in fire alarm reliability due to the above-mentioned non-fire alarms.

Republic of Korea Patent Publication No. 10-2364021 (announced on February 17, 2022)

The present invention can provide a method and system that can effectively prevent non-fire alarms to prevent increased casualties and unnecessary waste of firefighting power due to a decrease in fire alarm reliability due to non-fire alarms.

According to one aspect of the present invention, in the method of preventing false alarms using a P-type receiver including a detector and connected to an electric circuit installed in a plurality of districts, the receiver receives the measured voltage of the electric circuit from the P-type receiver in real time. receiving, a determining unit comparing the measured voltage with a plurality of preset voltage ranges to determine the state of the electric circuit including a normal state and a fire detection state, and if the recovery unit determines that the fire is detected, the P-type receiver is A non-fire alarm comprising a step of restoring, and a step of determining that a non-fire alarm has occurred when the electric circuit is determined to be in a normal state by comparing the measured voltage after a set time has elapsed from the recovery point of the P-type receiver to a plurality of voltage ranges. A prevention method is provided.

The P-type receiver includes a main alarm bell, and the electric circuit includes a district alarm bell. In the stage of restoring the P-type receiver, the operation of the main alarm bell and the earth alarm bell may be suppressed to prevent confusion due to non-fire alarms. there is.

After the step of determining that a non-fire report has occurred, a step in which the transmitter transmits the global location information of the sensor that generated the non-fire report to the administrator terminal may be further included so that the cause of the non-fire report can be identified and action taken.

The plurality of voltage ranges may include a voltage range of 19 to 22 V, representing a normal state, and a voltage range of 2 to 7.9 V, representing a fire detection condition.

The state of the electric circuit further includes an abnormal state, the P-type receiver includes a main alarm bell, and the electric circuit includes a district alarm bell, and after the step of determining the state of the electric circuit, if it is determined to be in an abnormal state, a non-fire alarm In order to prevent confusion due to this, a step of suppressing the operation of the main alarm bell and the district alarm bell may be further included.

The abnormal state includes a first abnormal state resulting from an instantaneous change in the measured voltage due to a disturbance, the voltage range of the first abnormal state is included in the voltage range of the steady state, and in the step of determining the state of the electric circuit, the normal state If it is determined that the change rate per unit time of the measured voltage exceeds the set value, the determination unit may determine it to be in an abnormal state.

The abnormal state includes a second abnormal state due to a short circuit in the electric circuit, and the voltage range of the second abnormal state may be 0 to 1.9V.

The abnormal state includes a third abnormal state due to a problem occurring in the sensor and electric circuit, and the voltage range of the third abnormal state may be 8 to 16.9V.

The abnormal state includes a fourth abnormal state due to disconnection of the electric circuit, and the voltage range of the fourth abnormal state may be 23 to 24V.

After the step of determining the state of the electric circuit, if an abnormal state is determined, a step of the transmitter transmitting information on the occurrence of the abnormal state to the administrator terminal may be further included so that the cause of the abnormal state can be identified and action can be taken.

According to the present invention, a method and system that can effectively prevent non-fire alarms can be provided to prevent increased casualties and unnecessary waste of firefighting power due to a decrease in fire alarm reliability due to non-fire alarms.

1 is a flowchart showing a method for preventing false alarms according to an embodiment of the present invention.
Figure 2 is a configuration diagram showing a non-fire alarm prevention system according to another embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Terms such as first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, the non-fire alarm prevention method and system 100 according to the present invention will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, identical or corresponding components are assigned the same drawing numbers and Redundant explanations regarding this will be omitted.

First, a method for preventing false alarms according to an embodiment of the present invention will be described.

According to this embodiment, as shown in FIG. 1, in a method of preventing false fire reports using a P-type receiver 10 that includes a detector and is connected to an electric circuit installed in a plurality of districts, the receiver 110 In the step of receiving the measured voltage of the electric circuit from the P-type receiver 10 in real time (S110), the determination unit 120 compares the measured voltage with a plurality of preset voltage ranges to determine a normal state and a fire detection state. A step of determining the state of the electric circuit (S120), a step of restoring the P-type receiver 10 when the recovery unit 130 is determined to be in a fire detection state (S130), and the determination unit 120 performing a P-type receiver ( A method for preventing a non-fire alarm is provided, including a step (S150) of determining that a non-fire alarm has occurred when the electric circuit is judged to be in a normal state by comparing the measured voltage after a set time has elapsed from the recovery point of 10) with a plurality of voltage ranges. .

According to this embodiment, a method for effectively preventing non-fire alarms can be provided to prevent increased casualties and unnecessary waste of firefighting power due to a decrease in fire alarm reliability due to non-fire alarms.

Hereinafter, each step of the non-fire alarm prevention method according to this embodiment will be described with reference to FIGS. 1 and 2.

According to this embodiment, a method of preventing false alarms can be provided using a P-type receiver 10 that includes a detector and is connected to an electric circuit installed in a plurality of districts.

An electric circuit including a detector is installed for each district, that is, for each border area, and this electric circuit is electrically connected to the P-type receiver (10) installed in the management office, etc., and accordingly, the manager can use the P-type receiver (10). ) allows fire monitoring for multiple districts.

Here, the detector is a component that directly detects fire in an automatic fire detection facility, and the detector may include a differential heat detector using air expansion, a constant temperature heat detector using heat accumulation, and a smoke detector using smoke detection.

The receiver is a configuration that promotes fire evacuation by automatically sounding an alarm, etc. according to a fire detection signal from a detector, etc. Specifically, the P-type receiver 10 can be electrically connected to fire detection electrical circuits wired in each district. there is.

According to this embodiment, by using the existing P-type receiver 10 without the need to build a separate new fire detection system in the building, it is possible to effectively prevent false alarms and promote economic efficiency.

Here, a non-fire alarm means that the detector or P-type receiver 10 operates and issues a fire alarm depending on factors other than heat, smoke, or flame caused by a fire.

These non-fire alarm factors, in descending order of proportion, may include artificial factors such as human mischief or error, management factors such as moisture or poor management, and systemic factors such as aging facilities, poor construction, or equipment errors. .

According to this embodiment, as will be described below, specific methods that can effectively respond to each of the factors of the above-described non-fire alarm can be provided to prevent non-fire alarms.

In step 110, the receiver 110 may receive the measured voltage of the electric circuit from the P-type receiver 10 in real time.

The P-type receiver 10 collects the voltage of the electric circuit for each district measured in real time for each district. Accordingly, the receiver 110 determines the measured voltage of the electric circuit for each district collected by the P-type receiver 10 as a non-fire report. It can be received in real time.

In step 120, the determination unit 120 may determine the state of the electric circuit, including a normal state and a fire detection state, by comparing the measured voltage with a plurality of preset voltage ranges.

That is, the determination unit 120 can determine the state of the electric circuit by comparing the measured voltage received through the receiver 110 with a plurality of voltage ranges including voltage ranges representing the normal state and fire detection state of the electric circuit. there is.

The electric circuit may include a detector and be electrically connected to a termination resistance at the end. In this case, in a normal state electric circuit, the detector does not act as a resistance, so the voltage value can be determined according to the termination resistance.

On the other hand, in an electric circuit in a fire detection state, the voltage value of the electric circuit may change compared to the above-mentioned normal state as the activated detector acts as a resistor with a resistance value significantly smaller than the termination resistance.

In step 130, if the recovery unit 130 is determined to be in a fire detection state, the P-type receiver 10 may be recovered.

In other words, when the recovery unit 130 determines that the state of the electric circuit is in a fire detection state, it suspends the judgment on the occurrence of a fire depending on the possibility of non-fire alarm generation and determines whether the detector was activated according to the fire. The receiver 10 can be recovered.

Here, recovery refers to a kind of reset process that returns the operating state of the P-type receiver 10 to its previous state according to reception of a fire detection signal, through which it is possible to verify whether or not it is a non-fire report.

In step 150, the determination unit 120 compares the measured voltage after the elapse of a set time from the recovery point of the P-type receiver 10 with a plurality of voltage ranges, and if the electric circuit is determined to be in a normal state, it may be determined that a non-fire alarm has occurred. there is.

That is, after restoring the P-type receiver 10, the determination unit 120 compares the measured voltage after the elapse of the set time with a plurality of voltage ranges, and if it is determined to be in a normal state, it can finally determine that a non-fire alarm has occurred.

Accordingly, not only can the recovery function of the P-type receiver 10 be effectively utilized, but it is also possible to significantly reduce the occurrence of non-fire alarms.

The P-type receiver 10 includes a main alarm bell, and the electric circuit includes a district alarm bell. In the step (S130) of restoring the P-type receiver 10, the main alarm bell is used to prevent confusion due to non-fire alarms. and the operation of the district alarm may be suppressed.

In this case, the suppression unit 140 temporarily considers the predetermined fire detection state as being based on a non-fire report until verification of whether or not it is a non-fire report is completed, and prevents unnecessary confusion that may be caused by such a non-fire report. For this reason, the main alarm bell and the district alarm bell can be stopped from ringing.

After the step of determining that a non-fire report has occurred (S150), the transmitter 160 transmits the earth location information of the sensor that generated the non-fire report to the manager terminal 20 so that the cause of the non-fire report can be identified and action can be taken. (S160) may be further included.

Accordingly, when it is confirmed that a non-fire report has occurred, the global location information of the detector that caused the non-fire report is transmitted to the manager terminal 20 to allow the manager to move to the relevant location to determine the cause and take necessary measures, thereby preventing future occurrences. It is possible to effectively block the possibility of possible false alarms.

The plurality of voltage ranges may include a voltage range of 19 to 22 V, representing a normal state, and a voltage range of 2 to 7.9 V, representing a fire detection state.

More preferably, the voltage range indicating the fire detection state may be 3.3 to 6.6V.

Meanwhile, the state of the electric circuit further includes an abnormal state, the P-type receiver 10 includes a main alarm bell, the electric circuit includes a district alarm bell, and after the step (S120) of determining the state of the electric circuit, If an abnormal condition is determined, a step (S142) in which the suppressor 140 suppresses the operation of the main alarm bell and the district alarm bell may be further included to prevent confusion caused by a non-fire alarm.

As mentioned above, non-fires can occur in the state of fire detection due to artificial factors such as pranks or mistakes by onlookers, as well as management factors such as moisture or poor management, or systematic problems due to aging equipment, poor construction, or equipment errors. It may be caused by several factors.

Therefore, the determination unit 120 further determines the abnormal state of the electric circuit to be able to respond to the non-fire alarm caused by administrative factors or system factors in addition to artificial factors, and accordingly, the suppression unit 140 determines the non-fire alarm according to the abnormal condition. To prevent unnecessary confusion that may be caused by the main alarm bell and the district alarm bell, you can stop ringing.

The abnormal state includes a first abnormal state resulting from an instantaneous change in the measured voltage due to a disturbance, the voltage range of the first abnormal state is included in the voltage range of the normal state, and in the step of determining the state of the electric circuit (S120) If it is determined to be in a normal state, the determination unit 120 may determine it to be in an abnormal state if the rate of change per unit time of the measured voltage exceeds the set value.

Here, the first abnormal state may be an abnormal state in which the measured voltage of the electric circuit suddenly changes suddenly due to a disturbance such as noise generation, motor startup, or lightning surge.

However, in the first abnormal state, except for an instantaneous sudden change in the measured voltage, the voltage range is included in the voltage range of the normal state. Accordingly, the determination unit 120 determines the unit of the measured voltage again for the case where it is determined to be in the normal state. By comparing the rate of change per hour with the set value, it is possible to determine whether it is in an abnormal state depending on whether it exceeds it.

The abnormal state includes a second abnormal state due to a short circuit in the electric circuit, and the voltage range of the second abnormal state may be 0 to 1.9V.

In other words, if a short circuit occurs in an electric circuit due to an error when replacing a detector or carelessness during construction inside a building, the voltage of the electric circuit drops sharply compared to the normal state, so in this case, it can be judged as an abnormal state.

The abnormal state includes a third abnormal state due to a problem occurring in the sensor and electric circuit, and the voltage range of the third abnormal state may be 8 to 16.9V.

In other words, problems with the detector and electrical circuit may occur due to aging or defective detectors, moisture infiltration or condensation inside the detector, defective electrical wiring such as short circuit, incorrect wiring, or poor insulation, terminal block corrosion, excessive installation of the detector, etc. In this case, a voltage drop occurs within the electric circuit compared to the normal state, so in this case, it may be judged to be an abnormal state.

The abnormal state includes a fourth abnormal state due to disconnection of the electric circuit, and the voltage range of the fourth abnormal state may be 23 to 24V.

In other words, if an open electrical circuit occurs due to carelessness during firefighting or interior construction inside a building, or poor connection to a detector or terminal block, the voltage of the electrical circuit rises rapidly compared to the normal state, so in this case, it is in an abnormal state. can be judged.

After the step of determining the state of the electric circuit (S120), if an abnormal state is determined, the transmitter 160 transmits information on the occurrence of the abnormal state to the manager terminal 20 so that the cause of the abnormal state can be identified and action can be taken. Step S170 may be further included.

If it is determined to be an abnormal state including the above-described first abnormal state, second abnormal state, third abnormal state, and fourth abnormal state, the transmitter 160 transmits information about the occurrence of the abnormal state to the manager terminal 20. By doing so, the manager can check the abnormal condition and take immediate action, effectively preventing future non-fire reports from occurring.

Next, a non-fire alarm prevention system 100 according to another embodiment of the present invention will be described.

According to this embodiment, as shown in FIG. 2, in a system for preventing false alarms using a P-type receiver 10 that includes a detector and is connected to an electric circuit installed in a plurality of districts, the P-type receiver ( A receiving unit 110 that receives the measured voltage of the electric circuit in real time from 10), a determination unit 120 that compares the measured voltage with a plurality of preset voltage ranges to determine the state of the electric circuit, including a normal state and a fire detection state. ), and a recovery unit 130 that restores the P-type receiver 10 when it is determined to be in a fire detection state, and the determination unit 120 measures the measured voltage after a set time has elapsed from the time of recovery of the P-type receiver 10. A non-fire alarm prevention system 100 is provided that compares a plurality of voltage ranges and determines that a non-fire alarm has occurred when the electric circuit is determined to be in a normal state.

According to this embodiment, a system that can effectively prevent non-fire alarms can be provided to prevent increased casualties and unnecessary waste of firefighting power due to a decrease in fire alarm reliability due to non-fire alarms.

Hereinafter, each configuration of the non-fire alarm prevention system 100 according to this embodiment will be described with reference to FIGS. 1 and 2.

According to this embodiment, a system for preventing false alarms can be provided using a P-type receiver 10 that includes a detector and is connected to an electric circuit installed in a plurality of districts.

The receiving unit 110 may receive the measured voltage of the electric circuit from the P-type receiver 10 in real time.

The determination unit 120 may determine the state of the electric circuit, including a normal state and a fire detection state, by comparing the measured voltage with a plurality of preset voltage ranges.

The recovery unit 130 can restore the P-type receiver 10 when it is determined to be in a fire detection state.

The determination unit 120 compares the measured voltage after a set time has elapsed from the recovery point of the P-type receiver 10 with a plurality of voltage ranges, and when the electric circuit is determined to be in a normal state, it may be determined that a non-fire alarm has occurred.

The P-type receiver 10 includes a main alarm bell, the electric circuit includes a district alarm bell, and the suppressor 140 can suppress the operation of the main alarm bell and the district alarm bell to prevent confusion due to non-fire alarms. there is.

The transmitter 160 may transmit the global location information of the sensor that generated the non-fire report to the manager terminal 20 so that the cause of the non-fire report can be identified and action taken.

The plurality of voltage ranges may include a voltage range of 19 to 22 V, representing a normal state, and a voltage range of 2 to 7.9 V, representing a fire detection state.

Meanwhile, the state of the electric circuit further includes an abnormal state, the P-type receiver 10 includes a main alarm bell, the electric circuit includes a district alarm bell, and the suppressor 140 provides a non-fire alarm when it is determined to be in an abnormal state. To prevent confusion, the operation of the main and district alarm bells can be suppressed.

The abnormal state includes a first abnormal state resulting from an instantaneous change in the measured voltage due to a disturbance, the voltage range of the first abnormal state is included in the voltage range of the normal state, and the determination unit 120 determines the normal state. The determination unit 120 may determine an abnormal state when the change rate per unit time of the measured voltage exceeds the set value.

The abnormal state includes a second abnormal state due to a short circuit in the electric circuit, and the voltage range of the second abnormal state may be 0 to 1.9V.

The abnormal state includes a third abnormal state due to a problem occurring in the sensor and electric circuit, and the voltage range of the third abnormal state may be 8 to 16.9V.

The abnormal state includes a fourth abnormal state due to disconnection of the electric circuit, and the voltage range of the fourth abnormal state may be 23 to 24V.

If an abnormal state is determined, the transmitter 160 may transmit information on the occurrence of the abnormal state to the manager terminal 20 so that the cause of the abnormal state can be identified and action can be taken.

Meanwhile, the components of the above-described embodiment can be easily understood from a process perspective. In other words, each component can be understood as a separate process. Additionally, the processes of the above-described embodiments can be easily understood from the perspective of the components of the device.

Additionally, the technical contents described above may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc., singly or in combination. Program instructions recorded on the medium may be specially designed and configured for the embodiments or may be known and available to those skilled in the art of computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -Includes optical media (magneto-optical media) and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, etc. Examples of program instructions include machine language code, such as that produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter, etc. A hardware device may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

Above, an embodiment of the present invention has been described, but those skilled in the art can add, change, delete or add components without departing from the spirit of the present invention as set forth in the patent claims. The present invention may be modified and changed in various ways, and this will also be included within the scope of the present invention.

10: P-type receiver
20: Administrator terminal
100: Non-fire alarm prevention system
110: receiving unit
120: Judgment unit
130: recovery unit
140: suppression unit
160: Transmitting unit

Claims (8)

In a method of preventing false alarms using a P-type receiver installed in a plurality of districts, connected to an electric circuit including a detector and a district alarm bell, and including a main alarm bell,
A receiving unit receiving the measured voltage of the electric circuit in real time from the P-type receiver;
A determination unit determining a state of the electric circuit including a normal state, a fire detection state, and an abnormal state by comparing the measured voltage with a plurality of preset voltage ranges;
When it is determined that the fire is detected, a suppression unit suppresses operation of the main alarm bell and the district alarm bell to prevent confusion caused by the non-fire alarm, and a recovery unit restores the P-type receiver;
The determination unit comparing the measured voltage after a set time has elapsed from the recovery point of the P-type receiver with the plurality of voltage ranges, and determining that the non-fire alarm has occurred when the electric circuit is determined to be in a normal state; and
When the abnormal state is determined, the suppression unit inhibits the operation of the main alarm bell and the district alarm bell to prevent confusion due to the non-fire alarm,
The above abnormal state is,
a first abnormal state resulting from an instantaneous change in the measured voltage due to at least one of disturbances including noise generation, motor startup, and lightning surge;
a second abnormal condition resulting from a short circuit in the electric circuit due to at least one of the following causes, including an error occurring when replacing the detector and carelessness during construction inside the building;
The sensor and the electric circuit due to at least one of the following causes: aging of the sensor, defective sensor, moisture penetration into the inside of the sensor, condensation inside the sensor, defective electrical wiring, corrosion of the terminal block, and excessive installation of the sensor. A third abnormal state due to a problem occurring in the upper body; and
A method of preventing a non-fire alarm, comprising a fourth abnormal condition resulting from disconnection of the electric circuit due to at least one of the causes including carelessness during construction inside the building, poor connection of the detector, and poor connection of the terminal block.
According to paragraph 1,
After the step of determining that the non-fire alarm has occurred,
A method for preventing a non-fire report further comprising the step of a transmitter transmitting earth location information of the sensor that generated the non-fire report to an administrator terminal so that the cause of the non-fire report can be identified and action taken.
According to paragraph 1,
The plurality of voltage ranges are,
a voltage range of 19 to 22 V, representing the steady state, and
A non-fire alarm prevention method comprising a voltage range of 2 to 7.9 V indicating the fire detection state.
According to paragraph 1,
The voltage range in the first abnormal state is included in the voltage range in the normal state,
In the step of determining the state of the electric circuit,
When the normal state is determined, the determination unit determines the abnormal state when the rate of change per unit time of the measured voltage exceeds a set value.
According to paragraph 1,
The voltage range of the second abnormal state is 0 to 1.9V.
According to paragraph 1,
The voltage range of the third abnormal state is 8 to 16.9V.
According to paragraph 1,
The voltage range of the fourth abnormal state is 23 to 24V.
According to paragraph 1,
After determining the state of the electric circuit,
If it is determined that the abnormal state is present, the method of preventing a non-fire report further includes a step of transmitting information on the occurrence of the abnormal state to an administrator terminal by a transmitting unit so that the cause of the abnormal state can be determined and action can be taken.