KR101286567B1 - P type fire alarm control panel system capable of verifying false alarm and method thereof - Google Patents

Abstract

P-type fire alarm receiver according to an embodiment of the present invention and the line interface for generating a detection signal to be activated in a normal state or in an alarm state according to the degree of change in the voltage level of the signal line to which the plurality of detectors or transmitters, When the detected detection signal is generated, the operation of receiving the detection signal from the line interface after the interruption and resupply of the DC voltage applied to the signal line is repeated a predetermined number of times. It may include a false alarm determination unit for determining the detection signal as a real fire alarm if the signal is activated, and otherwise determines as a false alarm.

Description

P-type fire alarm receiver system and false alarm judging method to check for false alarms {P TYPE FIRE ALARM CONTROL PANEL SYSTEM CAPABLE OF VERIFYING FALSE ALARM AND METHOD THEREOF}

The present invention relates to a P-type fire alarm receiver, and more particularly, to a P-type fire alarm receiver that can determine a false alarm.

Conventional P-type fire alarm receiver systems typically have multiple short signal detectors or transmitters connected in parallel via a single signal line cable.

In the case of a short signal type detector, a voltage of 24 V DC is applied, and the voltage drop of the signal line generated when the internal sensing circuit is short-circuited by fire heat, spark or smoke, or short-circuit by human switch pressing operation. By sensing, it is configured to know the fire occurrence in the area where the signal line is arranged.

Under normal circumstances, the signal line should maintain a constant voltage. However, after a long period of several years to several decades, unless there is a fire after installation, deterioration of insulation characteristics due to corrosion, degeneration or moisture, surge or lightning may occur. Due to voltage induction by commercially installed AC power lines or telephone lines using direct current 48V, instantaneous voltage drop may occur on the signal line itself, which usually leads to false alarms, malfunction of the detector and failure.

In addition, the detector itself may age and generate false signals.

Indeed, in many buildings, false alarms are observed due to aging lines, voltage induction, and aging of detectors, and many landlords make the wrong choice to turn off the fire alarm system instead of replacing signal lines and eliminating the cause.

In order to prevent such a false alarm, instead of issuing an alarm immediately when a signal is detected through the signal line, a 'non-fire protection device' is proposed that issues an alarm only when the signal is maintained for a predetermined accumulation time. Non-fire alarms can be installed in the terminal block of the fire alarm receiver to reduce false alarms.

The problem to be solved by the present invention is to provide a fire alarm receiver system and a false alarm determination method that can determine whether or not the false alarm of the signal line.

P-type fire alarm receiver according to an aspect of the present invention,

A line interface for generating a detection signal in which a plurality of detectors or transmitters are activated to a normal state or to an alarm state according to a degree of change of a voltage level of a signal line to which the plurality of detectors or transmitters are connected; And

When the activated detection signal is generated, the operation of receiving the detection signal from the line interface after a predetermined number of times is temporarily repeated after the supply of the DC voltage applied to the signal line is temporarily interrupted and then supplied again. If the detection signal has been activated for a predetermined number of times it may include a false alarm determination unit for determining the detection signal as an actual fire alarm, otherwise determine as a false alarm.

According to one embodiment, the P-type fire alarm receiver,

When the reset signal is applied to the power supply to temporarily shut off the supply of the DC voltage to the signal line, and further includes a power supply unit,

The false alarm determination unit increases the value of the repetition detection flag by 1 when identifying the activated detection signal, applies the reset signal to the power supply unit, and determines the detection signal as an actual fire alarm when the repetition detection flag reaches N. It can work.

According to one embodiment, the false alarm determination unit,

If the detection signal received after the supply of the DC voltage applied to the signal line is temporarily cut off and re-supplied, it may be operated to determine as a false alarm.

P-type fire alarm receiver system according to another aspect of the present invention,

A signal line with detectors or transmitters connected in parallel; And

Generates a detection signal that is deactivated to a normal state or activated to an alarm state according to the degree of change of the voltage level of the signal line, and when the activated detection signal is generated, temporarily cuts off the supply of DC voltage applied to the signal line. Repeat the operation of receiving the detection signal again a predetermined number of times after resupplying, and if the detection signal has been activated for the predetermined number of times, the detection signal is determined to be an actual fire alarm; It may include a P-type fire alarm receiver to determine.

False alarm determination method of the P-type fire alarm receiver according to another aspect of the present invention,

Generating a detection signal at the P-type fire alarm receiver such that the detectors or transmitters are deactivated to a normal state or activated to an alarm state according to the degree of voltage level variation of signal lines connected in parallel;

When the activated detection signal is generated, repeating the operation of receiving the detection signal a predetermined number of times after temporarily shutting off and resupplying the DC voltage applied to the signal line; And

If the detection signal has been activated for the predetermined number of times, the detection signal may be determined to be an actual fire alarm, and if not the false alarm.

According to an embodiment, when the activated sensing signal is generated, repeating the operation of receiving the sensing signal after a predetermined number of times after temporarily shutting off and resupplying the DC voltage applied to the signal line. Is,

Increasing the value of the repetition detection flag by one upon identification of the activated detection signal;

Temporarily shutting off the DC voltage supplied to the signal line and then resupplying the voltage; And

When the repetition detection flag reaches N, the method may further include determining the activated detection signal as an actual fire alarm.

According to one embodiment, the false alarm determination method of the P-type fire alarm receiver,

The method may further include determining that a false alarm is detected when the sensing signal is inactivated after the supply of the DC voltage applied to the signal line is temporarily interrupted and resupplied before the repetition sensing flag reaches N.

According to the P-type fire alarm receiver system and false alarm determination method of the present invention, instead of simply issuing a fire alarm when a signal is continuously detected during the accumulation time, the P-type fire alarm receiver actively resets the detector so that the signal line Not only faults but also false alarms caused by faulty detectors can be dealt with.

In addition, according to the P-type fire alarm receiver system and false alarm determination method of the present invention, even if additional non-fire protection is not added, the hardware design is changed, or even if detectors that have no return function or incompatible are installed, false alarms are prevented. It can be made into a P-type fire alarm receiver system.

1 and 2 are conceptual diagrams illustrating a P-type fire alarm receiver system according to an embodiment of the present invention.
3 is a flowchart illustrating a false alarm determination method in a P-type fire alarm receiver system according to an embodiment of the present invention.

For the embodiments of the invention disclosed herein, specific structural and functional descriptions are set forth for the purpose of describing an embodiment of the invention only, and it is to be understood that the embodiments of the invention may be practiced in various forms, The present invention should not be construed as limited to the embodiments described in Figs.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 and 2 is a conceptual diagram illustrating a P-type fire alarm receiver system according to an embodiment of the present invention.

1 and 2 together, the P-type fire alarm receiver system 10 includes a plurality of monitoring zones 11 in which a plurality of short-signal detectors 111 or transmitters 112 are connected in parallel to the signal line 113. The P-type fire alarm receiver 12 may monitor a voltage level of the plurality of signal lines 113.

Briefly describing the wiring of the signal line 113 for the reception of the fire alarm, the short signal type detector 111 and the transmitter 112 are connected in parallel to the signal line 113 terminated by the terminating resistor 114, The signal line 113 is designed such that a predetermined direct current voltage, for example, a direct current 24 V voltage according to the relevant regulations, is applied from the P-type fire alarm receiver 12 or from another power supply.

The short signal type detector 111 is designed such that the internal resistance is rapidly lowered or short-circuited when a flame, heat or smoke caused by a fire is applied to a predetermined level or more, and the transmitter 112 is pressed by an external force pressed by a person who finds a fire. As the switch is closed, the internal resistance is lowered and the alarm is triggered by a change in the voltage level.

A typical P-type fire alarm receiver monitors the level of the DC voltage applied to the signal line 113, and then responds to the equivalent resistance of the signal line 113 when the internal resistance of the short signal type detector 111 or the transmitter 112 suddenly drops. Therefore, by detecting a voltage change of the DC voltage level falls from 24V to 5V, it can generate an alarm.

In detail, the P-type fire alarm receiver 12 may include a line interface 121, a detector 122, a false alarm determiner 123, a controller 124, and a power supply 125.

The line interface 121 applies a 24V DC voltage supplied from the power supply unit 125 to the signal line 113, and detects a change in the voltage level of the signal line 113 by the sensing unit 122 to detect the detection signal S1. Create At this time, the detection signal S1 may be a measurement of the signal line voltage level, but is preferably activated to have a value of 0 or 1 meaning normal or alarm depending on a result of comparing the signal line voltage level with a predetermined alarm threshold voltage level. It may be a digital signal.

The false alarm determination unit 123 determines whether the activated detection signal S1 is caused by a voltage change caused by a transient and non-fire factor occurring in the signal line 113 or by a malfunction of the detector 111. The DC voltage applied to the signal line 113 is temporarily cut off from the P-type fire alarm receiver 12 and then resupplied to identify whether the detection signal S1 is activated according to the voltage level of the signal line 113. By repeating the operation to be performed a predetermined number of times, it is possible to determine whether or not a false alarm is present.

In detail, when the detection signal S1 of the detection unit 122 is activated for the first time, the false alarm determination unit 123 increases the value of the repetition number flag by 1 and cuts off the 24V DC voltage to the power supply 125. The reset signal RS instructing resupply is applied, and the detector 111 waits for a time to be initialized.

Subsequently, the false alarm determination unit 123 detects the state of the detection signal S1 on the corresponding signal line 113, and when the detection signal S1 of the detection unit 122 is activated, the value of the repetition number flag is N. It increments by one until it reaches, and applies the reset signal RS which instructs the power supply 125 to cut off and resupply the 24V DC voltage, and repeats the operation of waiting for the time when the detector 111 is initialized.

When the 24V DC power is cut off, the short signal type detector 111 returns to a state before detecting a fire. For example, in the case of a constant temperature detector using a thermistor and a relay having negative thermal resistance characteristics, the relay operates and the voltage level of the signal line 113 increases as the current flowing through the thermistor increases due to the heat of the fire. If the current no longer flows after the DC power is cut off, the relay falls and returns to its original state. If a fire actually occurs, the relay will operate immediately when the supply of DC power is resumed and the voltage level of the signal line 113 will also appear immediately low.

Therefore, if the repetition count flag is n (where n <N) and the detection signal S1 according to the voltage level of the signal line 113 is still activated after the blocking and resupply of the DC voltage, the corresponding alarm is It is likely a real alarm. However, in the present invention, such monitoring is repeated N times in order to reliably determine the false alarm.

If the detection signal S1 of the signal line 113 is identified as being inactive before the value of the repetition number flag reaches N, the false alarm determining unit 123 may determine the alarm as a false alarm. For example, in the above example, when the detection signal S1 is temporarily activated due to a momentary voltage excitation in the signal line 113 in which the constant temperature detector is installed, the activation state of the detection signal S1 is kept long. Since the relay of the detector cannot be separated, the voltage of the signal line 113 will rise to a normal level soon.

Furthermore, even if there is a case where a fire actually occurs and the detection signal S1 is temporarily deactivated during the false alarm determination, it can be determined as a real alarm within a few seconds since the detection signal S1 will be activated immediately thereafter.

The repeat count flag is then initialized and the alert can be discarded as a false alarm.

The controller 124 may control operations of the detector 122, the false alarm determiner 123, and operations of other components.

In addition, the control unit 124 may ignore the false alarm according to the determination result of the false alarm determining unit 123, and may notify the remote administrator of the failure of the receiver system according to the number of false alarms.

In addition, when the false alarm determining unit 123 determines that the actual alarm, the control unit 124 may warn the occurrence of a fire in the building through an alarm siren or broadcast, and operate the wired / wireless communication means to remotely monitor the fire. Notice or report to the authorities.

The power supply unit 125 supplies an appropriate DC voltage to the signal line 113 at normal times, and when the reset signal is applied, temporarily cuts off the supply of the DC voltage and then supplies it again.

3 is a flowchart illustrating a false alarm determination method according to an embodiment of the present invention.

Referring to FIG. 3, the false alarm determination method of the P-type fire alarm receiver system 10 has a value of the repetition count flag for the signal lines 113 installed in the various monitoring zones 11 in the P-type fire alarm receiver 12. In step S31, monitoring of changes in voltage levels in the initialized state is started.

In step S32, when the detection signal S1 is activated in accordance with the change in the voltage level with respect to the specific signal line 113, the flow advances to step S33.

If the detection signal S1 is deactivated in step S32, the flow advances to step S36.

In step S36, it is checked whether the repetition number flag F is in an initialized state, and if the repetition number flag F is not an initial value, this is when the fire alarm disappears during the false alarm determination loop of steps S32 to S34. As a result, the flow advances to step S37 to determine a false alarm.

If the repetition number flag F is the initial value in step S36, the process returns to step S31 to continue monitoring the signal lines 113. FIG.

In step S33, the P-type fire alarm receiver 12 increases the value of the repetition number flag F by 1 (F ++), and if the value of the repetition number flag F does not reach N, in step S34. The DC voltage applied to the signal line 113 is temporarily interrupted and resupplyed for a predetermined interruption time, and then the flow returns to step S32.

Specifically, for example, the false alarm determining unit 123 of the P-type fire alarm receiver 12 is a reset signal (RS) instructing the power supply unit 125 to cut off and resupply the 24V DC voltage to the corresponding signal line 113. After the detector 111 waits for the time to be initialized, the sensor 122 identifies whether the detection signal S1 of the corresponding signal line 113 is activated.

If the value of the repetition number flag F that has increased by 1 reaches N, step S33 proceeds to step S35, and in step S35, the P-type fire alarm receiver 12 of the corresponding signal line 113 The detection signal S1 according to the change in the voltage level is determined as the actual alarm.

In other words, the P-type fire alarm receiver 12 determines that it is an actual alarm when steps S32 to S34 are repeated N times in succession.

Otherwise, if in step S32 the detection signal S1 of the corresponding signal line 113 is identified as inactive in step S32, the process proceeds to step S36, in which the repetition number flag F is set to an initial value of 0. If not, it is determined as a false alarm in step S37.

On the other hand, in step S32, since the DC voltage is temporarily cut off and resupplyed in step S34 with respect to the signal line 113 for determining the false alarm, the change in the voltage level should be sensed. Activation of the detection signal S1 between the nth determination and the n + 1th determination, taking into account the time taken for the detector 111 to initialize after the power is cut off and resupply and the time taken for the fire detection. Sufficient time intervals can be given to determine whether or not.

For example, when the relay of the detector 111 is dropped and then operated again due to the power cut off, it takes several ms to several tens of milliseconds for the transient noise to disappear and the voltage waveform to settle. 111) In consideration of the time to react to flame, heat and smoke, a time interval of several hundred ms to 1 second may be provided.

False alarm determination can be made within 5 to 10 seconds even if the power-off and standby steps are repeated N times.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art. Modifications are possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all of the equivalent or equivalent variations will fall within the scope of the present invention.

10 P type fire alarm receiver system
11 guard zone 111 detector
112 Transmitter 113 Signal Line
114 terminating resistor
12 Type P Fire Alarm Receiver 121 Line Interface
122 Detector 123 False alarm judgment
124 Control Unit 125 Power Supply Unit

Claims (7)

A line interface for generating a detection signal in which a plurality of detectors or transmitters are activated to a normal state or to an alarm state according to a degree of change of a voltage level of a signal line to which the plurality of detectors or transmitters are connected; And
When the activated detection signal is generated, the operation of receiving the detection signal from the line interface after a predetermined number of times is temporarily repeated after the supply of the DC voltage applied to the signal line is temporarily interrupted and then supplied again. If the detection signal has been activated for a predetermined number of times, the detection signal is determined to be an actual fire alarm, and the detection signal received after the supply of the DC voltage applied to the signal line is temporarily cut off and resupplied is deactivated. Fire alarm receiver comprising a false alarm determination unit for determining the false alarm. The power supply unit of claim 1, further comprising: a power supply unit which temporarily cuts off supply of the DC voltage to the signal line and supplies the power again when a reset signal is applied,
The false alarm determination unit increases the value of the repetition detection flag by 1 when identifying the activated detection signal, applies the reset signal to the power supply unit, and determines the detection signal as an actual fire alarm when the repetition detection flag reaches N. P-type fire alarm receiver, characterized in that the operation. delete A signal line with detectors or transmitters connected in parallel; And
Generates a detection signal that is deactivated to a normal state or activated to an alarm state according to the degree of change of the voltage level of the signal line, and when the activated detection signal is generated, temporarily cuts off the supply of DC voltage applied to the signal line. After receiving and resupplying, the operation of receiving the detection signal again is repeated a predetermined number of times, and if the detection signal is activated for the predetermined number of times, the detection signal is determined as an actual fire alarm and applied to the signal line. P-type fire alarm receiver system including a P-type fire alarm receiver for determining a false alarm if the detection signal received after the temporary supply of the DC voltage is temporarily cut off and re-supplied. Generating a detection signal at the P-type fire alarm receiver such that the detectors or transmitters are deactivated to a normal state or activated to an alarm state according to the degree of voltage level variation of signal lines connected in parallel;
Increasing the value of the repetition detection flag by one upon identification of the activated detection signal;
Temporarily shutting off the DC voltage supplied to the signal line and then resupplying the voltage;
Determining the activated detection signal as an actual fire alarm when the repetition detection flag reaches N; And
P-type fire alarm comprising the step of determining a false alarm if the received detection signal is inactive after the temporary supply of DC voltage applied to the signal line is temporarily cut off before the repeat detection flag reaches N. Method for determining false alarm of receiver. delete delete

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