KR20130091480A - Method for determining fire by using temperature sensor and fire extinguishing system for preventing malfunction using the method - Google Patents

Abstract

PURPOSE: A method for determining fire occurrence and a fire extinguishing system for preventing malfunctions using the method are provided to determine fire occurrence using accumulated values of change rates. CONSTITUTION: A fire extinguishing system for preventing malfunctions comprises a control unit (10), a temperature sensor (20), a humidity sensor (30), a gas sensor (40), and an operation unit (50). The control unit determines fire occurrence and controls an actuator to extinguish a fire. The temperature sensor measures temperatures and delivers results to the control unit. The humidity sensor measures humidity and delivers results to the control unit. The gas sensor measures gas leakage and delivers results to the control unit. The operation unit comprises a switch for operation or input. [Reference numerals] (10) Control unit; (20) Temperature sensor; (30) Humidity sensor; (40) Gas sensor; (50) Operation unit; (60) Fire extinguisher; (70) Gas blocking unit; (80) Warning lamp; (90) Speaker

Description

TECHNICAL FIELD [0001] The present invention relates to a method for determining a fire occurrence by a signal to a temperature sensor, and a malfunction prevention automatic fire extinguishing system using the method. [0002]

The present invention relates to a malfunction-proof automatic fire extinguishing system. The present invention also relates to a method for judging occurrence of a fire by a signal to a temperature sensor. And more particularly, to an automatic fire extinguishing system and a fire occurrence judging method for preventing a malfunction caused by a defect in a temperature sensor.

The automatic fire extinguishing system includes a sensor for detecting the occurrence of a fire, a transmitter for generating a fire signal, a receiver for receiving a fire signal transmitted from a transmitter, a repeater for relaying a fire signal of a transmitter to a receiver, And a fire alarm for alarming to be recognized as a fire alarm. In addition, a controller for controlling an automatic fire extinguisher or a gas breaker to receive a signal of the receiver and to evolve a fire is provided.

The fire detector includes a gas detection sensor and a temperature sensor. In a conventional automatic fire extinguishing system, when a signal input from a temperature sensor is sensed at a temperature equal to or higher than a predetermined threshold, it is recognized that a fire has occurred, an alarm is generated, and an automatic fire extinguisher or a gas circuit breaker is operated.

Recently, the use of automatic fire extinguishing system has been generalized, and damage caused by malfunction has been increasing. If the automatic fire extinguishing system malfunctions, it creates a sense of fear to the people, causes a time loss due to unnecessary evacuation, and causes accidents at the time of evacuation. In addition, there is a time-consuming economic loss in refilling the fire-fighting work due to the operation of the automatic fire extinguisher, and damage due to the second pollution due to the discharge of the fire extinguishing agent occurs.

Causes of malfunction of the automatic fire extinguishing system are the defects of the temperature sensor itself, the defects of the controller, the change of the time constant due to the aging of the electronic parts used in the automatic fire extinguishing system, and the influence of external noise. Particularly, it is known that a malfunction caused by a defect of the temperature sensor among the above-mentioned malfunction factors is most frequent. As the temperature sensor momentarily malfunctions due to an external unpredictable cause, or when the sensor deteriorates, the temperature measurement sensitivity changes, causing a malfunction.

An object of the present invention is to provide an automatic fire extinguishing system capable of preventing a malfunction caused by a defect in a temperature sensor as described above.

A fire occurrence determination method using a temperature value of a temperature sensor includes calculating a cumulative comparison value in which a rate of change of a measured temperature value is accumulated for a predetermined period of time, Outputting a fire alarm when the cumulative reference value is included in the range of the cumulative reference value and the measured temperature value is equal to or higher than a predetermined temperature value; .

The malfunction prevention automatic fire extinguishing system according to the present invention includes a temperature sensor and a controller for outputting a fire alarm when the measured temperature value of the temperature sensor is equal to or higher than a predetermined temperature value. In the malfunction preventing automatic fire extinguishing system according to the present invention, the control unit accumulates the rate of change of the measured temperature value for a predetermined time to calculate a cumulative comparison value, and the cumulative comparison value accumulates the rate of change of the temperature value at the time of occurrence of the fire And outputs a fire alarm when the measured temperature value is equal to or higher than a predetermined temperature value.

According to the present invention, even if the rate of change of the sensor suddenly changes greatly according to the ambient temperature, it is possible to prevent occurrence of a fire alarm due to a malfunction of the temperature sensor,

1 is a schematic view of a malfunction preventing automatic fire extinguishing system according to the present invention;
2 is an explanatory diagram for explaining a method for obtaining an accumulated reference value of a temperature change rate per ambient temperature at the time of occurrence of a fire
FIG. 3 is a graph showing an accumulated reference value of the rate of temperature change per ambient temperature obtained by the method described in FIG.
4 is an explanatory diagram for explaining a method of obtaining the cumulative temperature change rate comparison value
5 is a graph showing a comparison reference value of the rate of temperature change obtained by the method described in Fig.

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

FIG. 1 shows an embodiment of a malfunction preventing automatic fire extinguishing system 100 according to the present invention. The malfunction prevention automatic fire extinguishing system 100 according to the present embodiment includes a control unit 10 for determining occurrence of a fire and controlling an actuator for extinguishing the fire, a temperature sensor 20 for measuring the temperature and delivering it to the control unit 10 And a humidity sensor 30 for measuring the humidity and delivering the humidity to the control unit 10. Further, it includes a gas sensor 40 for measuring the leakage of the gas and delivering it to the control unit, and an operation unit 50 composed of a switch for operation or input. An operation signal of the operation unit 50 is inputted to the control unit 10. [

The control unit 10 receives the temperature value of the temperature sensor 20 and determines whether or not a fire has occurred. If it is determined that a fire has occurred, the control unit 10 outputs a command for operating the automatic fire extinguisher 60 or the gas circuit breaker 70. Further, it outputs a command for operating an alarm light 80 for instructing people to evacuate and a speaker 90 for delivering the evacuation broadcast.

The conventional automatic fire extinguishing system measures the temperature value of the temperature sensor in real time and simply compares the temperature value and the temperature change rate with the reference temperature value and the reference temperature change rate value to judge that it is a fire if the reference temperature value or the reference temperature change rate value is larger than the value There is a problem that a malfunction is caused when there is a defect in the temperature sensor.

On the other hand, the automatic fire extinguishing system of the present embodiment can prevent malfunction by using the cumulative coefficient of temperature change rate as a reference value of fire occurrence judgment. The reference value of the cumulative coefficient of the temperature change rate is stored in the memory of the control unit 10. [

The automatic fire extinguishing system 10 of the present embodiment includes a temperature sensor 10 and a control unit 10 for outputting a fire occurrence alarm when the measured temperature value of the temperature sensor is equal to or higher than a predetermined temperature value. The control unit 10 calculates a cumulative comparison value by accumulating the rate of change of the measured temperature value for a predetermined period of time, and the cumulative comparison value is included in the range of the cumulative reference value obtained by accumulating the rate of change of the temperature value at the time of occurrence of the fire , And a fire alarm is outputted when the measured temperature value is equal to or higher than a predetermined temperature value.

A method of determining the occurrence of a fire by the temperature value of the temperature sensor in the automatic fire extinguishing system 100 of the present embodiment will be described with reference to Figs. 2 to 5. Fig.

A method for determining occurrence of a fire according to the present invention includes the steps of calculating a cumulative comparison value in which a rate of change of a measured temperature value is accumulated for a predetermined time, Comparing the cumulative reference value with a cumulative reference value and outputting a fire alarm when the measured temperature value is equal to or higher than a predetermined temperature value.

First, the cumulative coefficient of the temperature change rate is obtained by measuring a temperature change and a temperature change rate of the temperature sensor by performing a fire test according to the temperature around the temperature sensor 20 installed. Referring to FIG. 2, the expected fire site temperature is measured at 0.5 second intervals, and the rate of temperature change is calculated and recorded. FIG. 3 is a graph showing the temperature change with time of the temperature sensor when the ambient temperature is 10 ° C, 20 ° C and 30 ° C. The temperature of the temperature sensor at the time of fire occurrence is set to be equal to or higher than 140 ° C., and the ten temperature change rate data before that temperature are successively sampled to calculate the cumulative sum. The time interval and the number of samples are determined through several tests to make a clear distinction between fire and non-fire. The accumulated reference value of temperature change rate obtained by the fire test is set to 10.47 and the error is set to -0.07 and +0.07, respectively, and the cumulative reference value range is set to 10.40 to 10.54.

FIG. 4 is a graph showing a measurement result obtained by sampling a temperature value and a temperature change rate with time of a temperature sensor. Figure 5 is a graphical representation of the results of Figure 4; As shown in FIG. 4, in the case of the sample test # 1, when the measured value of the temperature sensor becomes 140 ° C or more, the cumulative comparison value of the temperature change rate is 10.44. In the sample test # 2, the cumulative comparison value is 10.11 , And in the sample test # 3, the cumulative comparison value was 10.90. That is, only the sample test # 1 belongs to the cumulative reference value range, the temperature sensor recognizes that the temperature sensor is operating normally, judges that the fire has occurred, and outputs the fire occurrence alarm, and sample tests # 2 and # 3 indicate that the temperature sensor operates abnormally The fire alarm is not output.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications may be made without departing from the scope of the present invention.

10 control unit
20 Temperature sensor
30 Humidity sensor
40 gas sensor
50 control unit
60 fire extinguishers
70 Gas breaker
80 Alarm light
90 speakers
100 automatic fire extinguishing system

Claims (2)

Calculating a cumulative comparison value in which a rate of change of the measured temperature value is accumulated for a predetermined period of time,
Comparing the cumulative comparison value with a cumulative reference value obtained by accumulating a rate of change of a temperature value at the time of occurrence of a fire as measured in advance,
And outputting a fire alarm when the cumulative comparison value is included in the range of the cumulative reference value and the measured temperature value is equal to or higher than a predetermined temperature value. And a control unit for outputting a fire alarm when the measured temperature value of the temperature sensor is equal to or higher than a predetermined temperature value, the automatic fire extinguishing system comprising:
Wherein the controller calculates a cumulative comparison value by accumulating the rate of change of the measured temperature value for a predetermined time,
The cumulative comparison value is included in a range of cumulative reference values obtained by cumulatively accumulating the rate of change of the temperature value at the time of occurrence of the fire and the fire alarm is outputted when the measured temperature value is equal to or higher than a predetermined temperature value Temperature sensor malfunction prevention automatic fire extinguishing system.

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