KR100973476B1 - Automatic Fire Detection and Alarm Apparatus - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fire alarm detector, wherein an input power supply (DCV) is configured at an input terminal of a nonpolar rectifying bridge diode (BD), and a current input connected to the nonpolar rectifying bridge diode (BD) output terminal. A shunt regulator 10 having a constant characteristic with respect to a temperature for regulating the output voltage to stabilize the output voltage; A hysteresis voltage comparator 20 composed of two input terminals and having hysteresis voltage characteristics for preventing oscillation between voltages compared with a reference voltage; It is composed of an output drive circuit unit 40 for generating a signal for driving the output unit 50 for outputting a fire presence signal to the signal output from the hysteresis voltage comparator 20, the cathode stage of the shunt regulator 10 The current control resistors (Rin) are connected in series to adjust the current applied to the fire alarm detector circuit and to apply a low voltage.

Fire alarm, voltage comparator, regulator, time delay, current control

Description

Automatic Fire Detection and Alarm Apparatus}

The present invention relates to a fire alarm detector, and more particularly to a fire alarm detector for detecting and alarming the temperature change caused by the fire.

As a general fire alarm, an automatic fire detection system is composed of a detector equipped with a sensor for detecting a fire, a transmitter for directing a fire alarm by a person watching the fire, and other types of alarms and receivers. The receiver supplies power to the detector sensor, and when the detector sensor detects a fire, it sends a signal to the receiver, and the receiver visually expresses the fired area and at the same time the alarm of the fired area and the receiver is installed. It rings to remind people around you to evacuate from the fire.

The detector includes a heat detector that senses heat according to its type, a smoke detector that detects smoke, and a photoelectric and radioactive material that monitors the fire using light (light). Ionization sensors that detect them.

In general, heat detectors are the most commonly installed, which are based on thermal expansion of air, differential sensors using rapid changes in ambient temperature, and hetero alloys using heat deformation (bimetal principle). There is a constant temperature detector that operates when raised and a compensating formula that combines differential and constant temperature. Recently, many differential and constant temperature sensors using semiconductors, which use a semiconductor thermal sensor (thermistor) to form differential and constant temperature electronic circuits, have been applied.

As a related art of a fire alarm detector, Korean Utility Model Registration Publication No. 1993-3317 (Differential Spot Type Fire Detector Circuit) is used for displaying a fire signal detection circuit (1), an accumulation and SCR firing circuit (2), and It is composed of the outgoing circuit (3), so that no operational amplifier is used, so that the current consumption is small and the rate of change of temperature is extremely easy.

Further, as a prior art, Korean Utility Model Registration Publication No. 1993-5416 (Fire Detector) includes a fire detector 1, a signal processor 2, a filter 3, a signal transmitter 4, and a non-polar circuit ( 5), three functions of differential, constant temperature, and compensation are composed of one sensor so that the function can be selectively used by adjusting switch or semi-fixed resistance.

As described above, the conventional differential and constant temperature detectors are configured by mechanical or mechanical methods of the thermal sensing means of the sensor, and thus the thermal sensing means are vulnerable to external shocks and vibrations, and cause factors such as switch contact failure. It consisted of easy configuration. In addition, the semiconductor sensor implements an internal circuit using an input voltage of 24 V. Therefore, a high resistance resistor and a high value thermistor have been used to implement a low current circuit.

The present invention is to solve the above problems, by implementing a voltage through the output of the non-polarity rectified bridge diode circuit in the form of supplying power to the circuit through the shunt regulator, it is possible to adjust the required current supplied to the circuit, It is an object of the present invention to provide a fire alarm detector in which a circuit configuration can be implemented at a low cost by supplying a low voltage to the functional circuit part, so that a high precision low value thermistor can be used when the thermistor is used as an external heat sensing element.

In order to achieve the above object, the present invention provides a fire alarm detector in which an input power source is configured at an input terminal of a nonpolar rectifying bridge diode, and outputs a constant voltage by controlling a current input connected to the nonpolar rectifying bridge diode output terminal. A shunt regulator having a constant characteristic with respect to a temperature for stabilizing it; A hysteresis voltage comparator composed of two input terminals and having hysteresis voltage characteristics for preventing oscillation between voltages compared with a reference voltage; A fire alarm comprising an output drive circuit unit for generating a signal for driving the output unit for outputting a fire presence signal as a signal output from the hysteresis voltage comparator, the current control resistor is connected in series to the cathode end of the shunt regulator It is characterized by the provision of a detector.

In addition, the present invention, in the fire alarm detector, the input power supply is configured at the input terminal of the non-polar rectified bridge diode, the temperature for stabilizing the output voltage by outputting a constant voltage by controlling the input current connected to the non-polar rectified bridge diode output terminal A shunt regulator having certain characteristics with respect to; A hysteresis voltage comparator composed of two input terminals and having hysteresis voltage characteristics for preventing oscillation between voltages compared with a reference voltage; It consists of an output drive circuit for generating a signal for driving the output unit for outputting a fire presence signal with the signal output from the hysteresis voltage comparator, the current control resistor is connected in series to the cathode end of the shunt regulator, the cathode end and the anode end It is characterized by providing a fire alarm detector with a divider resistor connected to it, and a feedback voltage setting pin connected between the divider resistor and the feedback terminal of the shunt regulator.

The present invention can control the current applied to the fire alarm detector circuit by the above-mentioned solving means, and can output a constant voltage irrespective of the sensing temperature, and supply a low voltage to the circuit to provide a high precision low value thermistor It can be applied to reduce the manufacturing cost of the detector for fire alarm.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention, a fire alarm detector will be described in detail.

1 is an embodiment according to the present invention, Figure 1 is a first embodiment according to the present invention, a configuration diagram when the voltage of the shunt regulator is fixed in the detector circuit for fire alarm.

An input power source (24 VDC) is connected to the input terminal of the nonpolar rectifying bridge diode (BD) and configured to supply power to the circuit through the shunt regulator (10). In the nonpolar rectifying bridge diode BD, the polarity of the voltage at the output terminal is constant even if the polarity of the input terminal is changed.

The shunt regulator 10 has a constant characteristic with respect to a temperature for stabilizing the output voltage by outputting a constant voltage by controlling the input current connected to the non-polar rectifying bridge diode (BD) output terminal. In the first embodiment, when the voltage of the shunt regulator 10 is fixed, the current required by the current setting resistor Rin can be controlled.

That is, the input power supply (24 VDC) applied to the fire alarm detector passes through a nonpolar rectifying bridge diode (BD) circuit and the current setting resistor Rin at the cathode of the shunt regulator 10 and the anode end of the shunt regulator 10. Is applied to ground.

At this time, a constant voltage is output through the cathode of the shunt regulator 10 regardless of the temperature. This is the case that the shunt regulator 10 which can set the voltage by the feedback voltage setting pin VF and voltage setting voltage divider R1 and R2 in the shunt regulator 10 of Example 3 and Example 4 is applied. .

In the fire alarm detector circuit of the present invention, the shunt regulator 10 is capable of being regulated through a current setting resistor Rin so as to generate a constant voltage and supply only a necessary current to each functional circuit part of the detector circuit.

Conventional fire alarm detectors use the input power supply (24 VDC) as a voltage applied through a nonpolar rectified bridge diode circuit or by using a zener voltage. However, in this case, the magnitude of the voltage varies depending on temperature. There are disadvantages. Therefore, this problem can be overcome by the circuit configuration of the present invention.

The hysteresis voltage comparator 20 is composed of two input terminals, and has a hysteresis voltage characteristic for preventing a phenomenon of oscillation between a voltage compared with a reference voltage. Referring to the application example of the constant temperature detector of FIG. 5, the hysteresis voltage comparator 20 includes a voltage divider R11 and R12 connected to a constant voltage source at a first input terminal Vin + of the comparator IC1. Is applied as a reference voltage, and the voltage division of the resistor R13 and the thermistor Tha is connected to the second input terminal Vin- of the comparator IC1 from the constant voltage source, and the external temperature change is transmitted through the thermistor Tha. And to detect.

In addition, in the application example of FIG. 6, the hysteresis voltage comparator 20 is applied to the first input terminal Vin + of the comparator IC2 as a reference voltage via voltage divider resistors R21 and R22 connected to a constant voltage source, and from the constant voltage source. A constant temperature detector may be configured to detect an external temperature change through the diode D20 by connecting the divided portion of the constant current source I20 and the diode D20 to the second input terminal Vin− of the comparator IC2. .

Referring to the application example of the differential detector of FIG. 7, the hysteresis voltage comparator 20 includes a voltage divider R31 and R32 connected to a constant voltage source at a first input terminal Vin- of the comparator IC3. The voltage is applied to the reference voltage through the voltage source, and the voltage divider of the thermistor Th30 and the thermistor Th31 is connected to the second input terminal Vin + of the comparator IC3 from the constant voltage source, and the thermistor Th30 mounted inside the detector, The differential detector is configured to detect a temperature change of the thermistor Th31 mounted outside the detector and exposed to detect the temperature in the form of a voltage between the thermistor Th30 and the thermistor Th31.

In addition, referring to another application of the differential detector of FIG. 8, the hysteresis voltage comparator 20 includes a voltage divider portion of a resistor R41 and a thermistor Th40 connected to a constant voltage source at a first input terminal Vin + of the comparator IC4. Is applied as a reference voltage of the comparator IC4, the voltage divider of the resistor R42 and the thermistor Th41 is connected to the second input terminal Vin- of the comparator IC4 from the constant voltage source, and the hysteresis voltage comparator 20 The circuit is configured so that the width of the fluctuating temperature becomes the hysteresis voltage width. It is differential to detect the temperature change of the thermistor Th40 for detecting the internal temperature of the detector and the thermistor Th41 mounted outside the detector to detect the temperature in the form of a voltage between the thermistor Th40 and the thermistor Th41. The detector is configured.

In addition, referring to another application of the differential detector of FIG. 9, the hysteresis voltage comparator 20 divides the voltage of the constant current source I51 and the diode D51 connected to the constant voltage source at the first input terminal Vin + of the comparator IC5. The part is applied as the reference voltage of the comparator IC5, and the divided part of the constant current source I52 is connected to the second input terminal Vin- of the comparator IC5 from the constant voltage source. The current is applied to the two diodes D51 and D52 through I51 and I52 so as to be detected when the temperature changes from the set voltage. The circuit is configured such that the width of the fluctuation temperature of the hysteresis voltage comparator 20 becomes the hysteresis voltage width, the diode D51 detects the internal temperature of the detector, and the diode D52 mounted outside the detector to detect the temperature. The differential detector is configured to detect the temperature change in the form of a voltage between the diode D51 and the diode D52.

The time delay circuit unit 30 makes a delay of a predetermined time according to the output state of the hysteresis voltage comparator 20, and outputs an input signal of the output driving circuit unit 40 when the set time arrives, and the time delay circuit unit 30 When the sensor detects a change in ambient temperature like a differential detector or reaches a set temperature like a constant temperature detector, the state of the output of the hysteresis voltage comparator 20 changes, and operates a circuit that creates a time delay. When it reaches to generate an input signal for operating the output drive circuit (40). And the role of the time delay circuit unit 30 in the fire alarm detector includes a function to create a delay time of a predetermined predetermined time.

The output driving circuit unit 40 generates a signal for driving the output unit 50 that outputs a fire presence signal as a signal output from the hysteresis voltage comparator 20. The output unit 50 is a single element or an output circuit, such as SCR, the output terminal is operated to flow a constant current, and maintain the current to transmit a fire presence signal. The output unit 50 has a light emitting diode (LED) in parallel to visually indicate the operation.

FIG. 2 is a configuration diagram in which the time delay circuit unit is omitted in the first embodiment, and the time delay circuit unit 30 is omitted.

3 is a configuration diagram of a case where the voltage of the shunt regulator is variably applied to an external resistance in the fire alarm detector circuit. That is, the current control resistor Rin is connected in series to the cathode terminal of the shunt regulator 10, and the voltage divider resistors R1 and R2 are connected to the cathode terminal and the anode terminal, and between the voltage divider resistors R1 and R2 and the shunt regulator. The feedback voltage setting pin (VF) is connected to the feedback terminal of (10).

4 is a configuration diagram in which the time delay circuit unit is omitted in the third embodiment in the fire alarm detector circuit according to the fourth embodiment of the present invention.

While the invention has been shown and described in connection with specific embodiments thereof, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who has a can easily know.

1 is a configuration diagram when a voltage of a shunt regulator is fixed in a detector circuit for fire alarm as a first embodiment according to the present invention.

2 is a configuration diagram in which the time delay circuit part is omitted in the first embodiment in the fire alarm detector circuit according to the second embodiment of the present invention.

FIG. 3 is a configuration diagram when a voltage of a shunt regulator is variably applied to an external resistor in a fire alarm detector circuit according to a third embodiment of the present invention.

4 is a configuration diagram in which the time delay circuit unit is omitted in the third embodiment in the fire alarm detector circuit according to the fourth embodiment of the present invention.

5 and 6 are circuit diagrams showing an application example of a constant temperature detector as a hysteresis voltage comparator of a fire alarm detector according to the present invention.

7 to 9 are circuit diagrams illustrating an application example of a differential detector as a hysteresis voltage comparator of a fire alarm detector according to the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: shunt regulator 20: hysteresis voltage comparator

30: time delay circuit portion 40: output drive circuit portion

50: output section BD: non-polar rectifying bridge diode

Rin: Current setting resistor VF: Feedback voltage setting pin

R1, R2, R11, R12, R13, R21, R22, R31, R32, R41, R42: Resistance

IC1-IC5: Comparators Tha, Th30, Th31, Th40, Th41: Thermistor

D20, D51, D52: Diodes Ia, I51, I52: Constant Current Source

Claims (9)

delete delete delete delete delete A shunt regulator (10) connected to an output terminal of the nonpolar rectifying bridge diode (BD) for rectifying the input power source (DCV) to output a constant voltage by controlling input current to stabilize the output voltage, and having a constant characteristic with respect to temperature; A hysteresis voltage comparator 20 composed of two input terminals and having hysteresis voltage characteristics for preventing oscillation between voltages compared with a reference voltage; A time delay circuit unit 30 which makes a delay of a predetermined time according to the output state of the hysteresis voltage comparator 20 and outputs an input signal of the output driving circuit unit 40 when the set time is reached; An output driving circuit unit 40 for generating a signal for driving the output unit 50 for outputting a fire presence signal with the signal output from the hysteresis voltage comparator 20; and the cathode end of the shunt regulator 10 The resistor Rin is connected in series, and the divider resistors R1 and R2 are connected to the cathode and anode terminals, and the feedback voltage is set between the divider resistors R1 and R2 and the feedback terminal of the shunt regulator 10. In the fire detector connected to the dragon pin (VF), The hysteresis voltage comparator 20 is applied to the first input terminal Vin + of the comparator IC2 as a reference voltage through the voltage divider R21 and R22 connected to the constant voltage source, and is applied from the constant voltage source to the constant current source I20 and the diode ( And a constant temperature detector configured to connect the voltage dividing portion of the D20 to the second input terminal Vin- of the comparator IC2 to detect an external temperature change through the diode D20. delete delete A shunt regulator (10) connected to an output terminal of the nonpolar rectifying bridge diode (BD) for rectifying the input power source (DCV) to output a constant voltage by controlling input current to stabilize the output voltage, and having a constant characteristic with respect to temperature; A hysteresis voltage comparator 20 composed of two input terminals and having hysteresis voltage characteristics for preventing oscillation between voltages compared with a reference voltage; A time delay circuit unit 30 which makes a delay of a predetermined time according to the output state of the hysteresis voltage comparator 20 and outputs an input signal of the output driving circuit unit 40 when the set time is reached; An output driving circuit unit 40 for generating a signal for driving the output unit 50 for outputting a fire presence signal with the signal output from the hysteresis voltage comparator 20; and the cathode end of the shunt regulator 10 The resistor Rin is connected in series, and the divider resistors R1 and R2 are connected to the cathode and anode terminals, and the feedback voltage is set between the divider resistors R1 and R2 and the feedback terminal of the shunt regulator 10. In the fire detector connected to the dragon pin (VF), The hysteresis voltage comparator 20 applies the divided portion of the constant current source I51 and the diode D51 connected to the constant voltage source to the first input terminal Vin + of the comparator IC5 as the reference voltage of the comparator IC5, The divided portion of the constant current source I52 is connected from the source to the second input terminal Vin- of the comparator IC5, and the two diodes D51 and D52 are connected from the constant voltage source through two constant current sources I51 and I52. A fire alarm detector, comprising: a differential detector configured to apply a current to and detect a change in temperature from a set voltage.

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