KR101217800B1 - Fire detector of fixed temperature - Google Patents

Abstract

The problem to be solved by the present invention is to provide a constant temperature fire detector for simplifying the configuration of the constant temperature fire detector. The constant temperature fire detector of the present invention includes: a power supply unit rectifying alternating current by direct current to supply power for fire detection; And a fire detection unit receiving power from the power supply unit and changing a resistance at a specific temperature, generating a fire detection signal according to the change of the resistance, and continuously maintaining the fire detection signal for a predetermined time. It is done. According to the present invention, since a separate continuous circuit is not required for continuous power supply, it is possible to simplify the configuration of the constant temperature fire detector, thereby simplifying the manufacturing process and reducing the manufacturing cost and time. In addition, by simplifying the circuit configuration of the constant temperature fire detector, since a collision with other circuits does not occur, the reliability of the constant temperature fire detector is further improved.

Description

Fire detector of fixed temperature}

The present invention relates to a constant temperature fire detector, and more particularly, to a constant temperature fire detector using a metal-insulator phase transition phenomenon in order to simplify the configuration of the constant temperature fire detector.

In general, a fire detector is installed on the ceiling or wall to generate an alarm when a fire breaks out to prevent human injury.

Such a fire detector includes a fire detector that detects a fire by using a change of heat and a fire detector that detects a fire by using a change of smoke according to a fire detection method, and a fire detector that detects a fire by using a change of heat. There are a differential fire detector and a constant temperature fire detector, and a fire detector that detects a fire by using a change of smoke includes a photoelectric fire detector and an ionized fire detector.

Differential fire detectors detect fires using rapid changes in temperature, and constant temperature fire detectors detect fires when they reach a preset temperature using a bimetal or thermistor. In addition, the photoelectric fire detector detects fire based on whether light is blocked, and the ionic fire detector detects fire using radioactive materials.

Among the fire detectors described above, a constant temperature fire detector is mainly used, and the internal configuration of the constant temperature fire detector is as follows.

2 is a block diagram of the internal circuit of the conventional constant temperature fire detector, the power supply unit 10, the fire detection unit 20, the LED operation unit 30, the continuous circuit unit 40 and the signal processing unit 50 It is composed of

The power supply unit 10 rectifies alternating current into direct current using a bridge circuit composed of four diodes, and rectifies the rectified direct current into direct current having a constant size by means of a zener diode and a capacitor. The direct current rectified by the power supply unit 10 is supplied to a constant temperature fire detector.

Fire detection unit 20 of the conventional constant temperature fire detector is composed of a bimetal or thermistor, Figure 2 shows a constant temperature detector consisting of thermistor. In addition, there are two types of thermistors: PTC (Positive Temperature Coefficient), which increases resistance as temperature increases, and Negative Temperature Coefficient (NTC), which decreases resistance as temperature increases. do.

As the fire occurs and the temperature increases, the resistance of the fire detection unit 20 decreases, so that a current flows through the Q1 base terminal of the signal processing unit 50, so that Q1 operates, and Q1 operates, so that the base terminal of Q2 The current flows and Q2 operates.

As Q2 operates, a current flows through the base terminal of Q4 of the continuous circuit unit 40 to operate Q4. In addition, as Q4 operates, a current flows through the Q5 base terminal of the LED operating unit 30, so that Q5 operates. As Q5 operates, a current flows through the base terminal of Q6, causing Q6 to operate. Q6 operates to power the LED.

At this time, when the fire detection unit 20 detects a fire, power must be continuously supplied to the LED for a predetermined time in order to continuously inform the outside of the occurrence of fire, and the fire detection unit 20 to supply power continuously. The resistance of NTC of) should be kept constant.

However, since the resistance value of the NTC continuously changes according to the change in temperature, even if a fire occurs, the resistance value of the NTC increases when the temperature falls below a predetermined temperature, so that power is not continuously supplied to the LED. As a result, a problem arises in that the occurrence of fire cannot be continuously informed to the outside.

In order to prevent such a problem, the conventional constant temperature fire detector includes a continuous circuit unit 40, and the resistance of the NTC is increased so that even when no current is supplied to the base terminal of Q1, the Q3 and Q4 By interaction, current is supplied to the base terminal of Q4, and power is continuously supplied to the LED.

However, the above-described continuous circuit unit is additionally required for continuous power supply, which causes a problem in that the configuration of the constant temperature fire detector is very complicated.

In addition, the manufacturing process is complicated due to the complex configuration, which has a problem that the manufacturing time and cost significantly increased.

In addition, due to a complicated configuration, a collision occurs with another circuit, and there is a problem in that the reliability of the constant temperature fire detector is lowered.

In addition, in the case of a constant temperature fire detector using a bimetal or thermistor, after a certain time, the performance of the bimetal and thermistor is deteriorated, so that a sensitivity of detecting a fire is lowered.

The present invention has been made to solve the above problems,

The problem to be solved by the present invention is to provide a constant temperature fire detector for simplifying the configuration of the constant temperature fire detector.

In addition, the problem to be solved by the present invention is to provide a constant temperature fire detector for quickly detecting the occurrence of a fire.

In addition, the problem to be solved by the present invention is to provide a constant temperature fire detector for semi-permanent use by maintaining the measurement sensitivity of the fire.

The constant temperature fire detector includes: a power supply unit rectifying AC with a direct current to supply power for fire detection; And a fire detection unit receiving power from the power supply unit and changing a resistance at a specific temperature, generating a fire detection signal according to the change of the resistance, and continuously maintaining the fire detection signal for a predetermined time. It is done.

In addition, the fire detection unit is characterized by using a CTS (Critical Temperature Sensor) for detecting a fire by changing the resistance based on the metal-insulator phase transition phenomenon.

In addition, the CTS is characterized in that the resistance changes rapidly at a specific temperature.

In addition, the CTS is characterized in that the resistance decreases as the temperature rises.

According to the present invention, since a separate continuous circuit is not required for continuous power supply, it is possible to simplify the configuration of the constant temperature fire detector, thereby simplifying the manufacturing process and reducing the manufacturing cost and time.

In addition, by simplifying the circuit configuration of the constant temperature fire detector, since a collision with other circuits does not occur, the reliability of the constant temperature fire detector is further improved.

In addition, due to the characteristics of the CTS, the resistance changes rapidly at a predetermined temperature, so that the occurrence of a fire can be detected quickly.

In addition, although the measurement sensitivity decreases with time due to the characteristics of a conventional mechanical or electronic fire detector, the present invention has a remarkable effect that can be used semi-permanently by using a CTS using a metal-insulator phase transition phenomenon.

1 is a block diagram showing an embodiment of the present invention constant temperature fire detector.
Figure 2 is a block diagram showing a conventional constant temperature fire detector.
3 is a graph showing a change in resistance with temperature of CTS.

Hereinafter, a preferred embodiment of the present invention constant temperature fire detector will be described in detail with reference to the drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

Figure 1 shows an embodiment of the present invention constant temperature fire detector, the present invention is composed of a power supply 10 and the fire detection unit 20. In addition, the fire detection unit 20 may include an LED operation unit 30 for informing the outside of the result detected.

The power supply unit 10 rectifies AC to DC to supply power for fire detection. AC is rectified by a bridge circuit 11 composed of four diodes, and a rectified DC is rectified by a zener diode 12 and a capacitor 13 connected in parallel with the bridge circuit 11. Adjust

The direct current rectified by the power supply unit 10 is supplied to the fire detection unit 20 and the LED operation unit 30 for the fire detection.

The fire detection unit 20 receives power from the power supply unit 10 and the magnitude of the resistance changes according to the change in the external temperature, and the LED operation unit continuously emits the fire detection signal for a predetermined time according to the changed resistance value. Send to (30). That is, power is supplied to the LED operation unit 30 according to the value.

In addition, the fire detection unit 20 uses a CTS (Critical Temperature Sensor) to detect the fire by changing the resistance based on the metal-insulator transition (Metal-Insulator Transition) phenomenon.

Metal-insulator phase transition refers to the transition of a metal to an insulator or an insulator to a metal. In other words, if the coulombic energy is very large between the conductive conductors in the metal, the transition occurs suddenly to the mort insulator without structural change of the material.

In the CTS based on the metal-insulator phase transition phenomenon of the present invention, the insulator is phase-transformed into a metal at a temperature of 70 ± 2 ° C. or higher, thereby rapidly decreasing the size of the resistor and maintaining the reduced value of the resistor for a certain time. . That is, heat is generated when the insulator transitions to the metal due to the characteristics of the metal-insulator phase transition phenomenon, and the state transitioned by the heat can be continuously maintained for a predetermined time.

Table 1 below shows the characteristics of the CTS used in the present invention.

Symnol
Parameter
Value Units
T _A = 25 ℃ T _A ≥70 ℃ V _opmax Maximum operating voltage 50 10 V I _opmax Maximum operating current 0.010 40 mA I _opp Peak operating current 0.010 40 mA
R
Temperature sensor resistance Min Max Min Max 2.5M 3.5M 190 220 Ω

In other words, near 70 ° C, the state characteristic of the CTS changes rapidly. Above 70 ° C, V (voltage) decreases from 50V to 10V, and I (current) increases from 0.010mA to 40mA. In addition, R (resistance) decreases rapidly from 2.5MV to 3.5MV to 190V to 220V.

The present invention takes advantage of the characteristics of CTS in which the value of the resistance changes rapidly at a given temperature.

Figure 3 shows the change in resistance of the CTS with temperature changes, a sudden change in resistance occurs near 70 ℃. That is, near 70 ° C, the insulator causes a phase transition to the metal, and the resistance decreases drastically. As shown in FIG. 3, the resistance decreases rapidly, and thus, the resistance is rapidly reacted to an external temperature change, thereby prompting the occurrence of a fire.

In addition, the present invention, when the resistance value of the CTS is less than 2MΩ by the change of temperature, the LED operating unit 30 is operated to turn on the LED 31, when the resistance value of the CTS is more than 2MΩ LED operating unit 30 Since the LED 31 is not operated, it can be controlled to not turn on.

In addition, the temperature and resistance value at which the LED 31 operates in the present invention are not limited to the above description.

The LED operating unit 30 is composed of an LED 31 and a resistor 32. Power supplied from the power supply unit 10 is distributed by the resistor 32 and the CTS and supplied to the LED 31. At this time, when the CTS has a relatively large resistance, sufficient power for the operation of the LED 31 is not supplied, so that the LED 31 does not operate. When the CTS has a relatively low resistance, sufficient power is supplied for the operation of the LED 31, so that the LED 31 operates.

That is, since the resistance value of CTS is relatively large when the temperature is 70 ° C. or lower, the LED 31 does not operate because sufficient power is not supplied to the LED 31. When the temperature is 70 ° C. or higher, the resistance value of CTS is relatively high. Since small power is supplied to the LED 31, the LED 31 operates.

In addition, since heat is generated when the CTS transitions from an insulator to a metal, the CTS maintains a predetermined temperature without external heat supply, thereby continuously supplying power required for the operation of the LED.

As described above, the embodiments of the present invention are described, but the technical idea of the present invention is not limited to the above embodiment, and various constant temperature fire detectors may be implemented in a range that does not depart from the technical idea of the present invention.

10... Power supply
20... Fire Detection Department
30 ... LED operation part
40 ... Continuous circuit
50... The signal processor

Claims (4)

Rectifying AC to DC to supply a power supply for fire detection power;
A fire detection unit receiving power from the power supply unit and changing a resistance at a specific temperature, generating a fire detection signal according to the change of the resistance, and continuously maintaining the fire detection signal for a predetermined time; And
It includes an LED operation unit for emitting a fire detection signal generated by the fire detection unit to notify the outside of the fire detection state,
The fire detection unit detects a fire by changing resistance based on a metal-insulator phase transition phenomenon, and maintains a predetermined temperature without external heat supply by using heat generated when the phase transitions from an insulator to a metal. Constant temperature fire detector, characterized in that to use the CTS (Critical Temperature Sensor) to continuously maintain the power supplied to the predetermined time. delete The method of claim 1,
The CTS is a constant temperature fire detector, characterized in that the resistance changes rapidly at a specific temperature. The method of claim 3,
The CTS is a constant temperature fire detector, characterized in that the resistance decreases as the temperature rises.

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