KR890007023Y1 - Automatic on/off switching circuit - Google Patents

Abstract

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Description

Solid State Photoelectric Flasher

1 is a block diagram of the present invention.

2 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: sensing circuit 2: delay circuit

3: amplification circuit BD ₁ , BD ₂ : bridge rectification circuit

SC: Thyristor ZD: Zener Diode

OP ₁ , OP ₂ ,: OP amplifier CD: Optoelectronic device for light detection

C ₁ -C _3: Capacitor D ₁ , D ₂ : Diode

Q: transistor R ₁ -R ₁₂ : resistance

VR: Variable resistance CT: Trance

SW: Selection switch Vcc: Power terminal

a, b: Flasher connector

The present invention relates to a contactless photoelectric flasher, and in particular, by using a thyristor, a power control element, to turn off a fluorescent lamp or a discharge lamp at a solid state, and to provide a delay circuit to prevent flickering when the lamp is turned off. The main focus was on AC 110 and 220 volts.

In general, the auto flasher is designed to save the consumption strategy and provide the user's convenience by turning off the lamp (fluorescent lamp, discharge lamp, incandescent lamp) according to the illuminance of the external light.

The conventional auto flasher that operates like this has the inconvenience of using only the flasher corresponding to the used voltage because the voltage used is limited to AC 110 volts and AC 220 volts. Since the contact point does not occur at the initial stage due to a defective contact, but the long-term use causes the relay to be damaged due to a spark, etc., which causes the contact fault to occur, causing the flasher to malfunction. As a result, it had a drawback that the reliability of the flasher was low.

Therefore, the present invention can be used as a combination of AC 110/220 volts to solve the conventional problems as described above, and by automatically turning on the lamp (fluorescent lamp, discharge lamp) by using a thyristors as a power control element, so that the automatic The aim is to extend the life of the flasher and to improve reliability.

Hereinafter, a detailed description will be given with reference to the accompanying drawings.

As shown in FIG. 1, one terminal of the AC input power supply is directly connected to the lamp serving as the load, and the other terminal of the load and the other terminal of the AC input are connected to the terminal points (a) and (b), which are automatic flashers of the present invention.

The terminal points (a) and (b) are connected to the bridge rectifier circuit BD ₁ via the primary side of the current detection transformer CT and the selection switch SW, and to the output power terminal of the rectifier circuit BD ₁ . The thyristors SC, which is a power control element, are connected to each other and the DC power supply Vcc is output through the resistor R ₇ and the diode D ₁ .

In addition, the bridge rectifier circuit BD ₂ is connected to the secondary side of the transformer CT, and a capacitor C ₁ and a zener diode ZD are connected to output a constant voltage to the output of the rectifier circuit BD ₂ . Causes (Vcc) to be printed.

The gate of the power control thyristor (SC) can be turned on and off through a sensing circuit (1) for detecting the brightness of external light and a delay circuit (2) and an amplification circuit (3) configured to prevent flicker in case of flashing. It was made.

FIG. 2 is a detailed circuit diagram of an embodiment of the present invention, connecting a power factor-improving phase condenser C ₂ to the primary side of the rectifying point transformer T and outputting the bridge rectifier circuit BD ₁ and BD ₂ . Connect the voltage divider (R ₂ , R ₃ ) to the non-inverting terminal (+) of the OP amplifier (OP ₁ ) to the DC power supply terminal (Vcc), and set it as the reference voltage. The divided voltage according to the values of the resistor VR and the resistor R ₁ is input to the inverting terminal (-) of the OP amplifier OP ₁ to connect the positive feedback resistor R ₄ to correspond to light detection. The light sensing circuit 1 is configured to obtain an output.

The delay circuit 2 connects the resistor R ₁₃ (R ₆ ), the diode D ₂ , and the capacitor C ₃ to the output of the light sensing circuit 1, and divides the resistors R ₈ and R _9. The voltage divided by) is connected to the non-inverting terminal (+) of the OP amplifier OP ₂ to set the reference voltage, and the output of the delay circuit _{2 is} connected to the inverting terminal (-) of the OP amplifier OP ₂ . Inputs and connects the bias resistors R ₁₀ and R ₁₁ of the transistor Q to the output of the OP amplifier OP _2. The collector of the transistor Q has a resistor connected to the output of the sensing circuit 1. R ₅ ) and a resistor (R ₁₂ ) connected to the power supply terminal (Vcc) are connected to the amplification circuit (3), and the output of the amplification circuit (3) to switch the power control thyristors (SC) so that It is.

Referring to the operation and effect of the present invention as described above are as follows.

When the selector switch (SW ₁ ) is turned on, it is applied to the bridge rectifier circuit (BD ₁ ) through the AC power transformer (CT) primary side, but the current flowing through the current detection transformer (CT) is very small current. Very little voltage induced on the secondary side is charged to the capacitor C ₁ through the resistor R ₇ and the diode D ₁ through the output of the bridge rectifying circuit BD ₁ , and by the zener diode ZD. The stable DC power supply Vcc is output and supplied to the operating power supply of the sensing circuit 1, the delay circuit 2, and the amplification circuit 3. As shown in FIG.

At this time, OP amplifiers (OP ₁ ) (OP ₂ ) and voltage control resistors (R ₁ , R ₂ , R ₃ ) (R ₈ , R ₉ ) with high input impedance are set in the sensing circuit (1) and the amplifier circuit (3). When the current is reduced, the operating voltage can be used in a wide range from 90V-240V, and thus AC 110V and AC 220V can be used. The DC power is amplified with the sensing circuit 1 through the resistor R ₇ . The circuit 3 can be supplied.

In the DC power supply (Vcc), the voltage divided by the voltage dividing resistors R ₂ and R ₃ is set to the reference voltage of the OP amplifier OP ₁ and the brightness of the external light is bright in the light sensing photoconductive device CD. In this case, since the resistance value is low, a high potential is applied to the inverting terminal (-) input of the OP amplifier OP ₁ so that a low signal is output from the light sensing circuit 1, and when the external light is dark, the resistance of the photoconductive device CD is reduced. inverting terminal of standing low voltage OP amplifier (OP ₁₎ is increased, the value (-) is applied to the input, so standing the OP amplifier (OP _1), the non-inverting terminal (+) the reference voltage value is higher bridge light detecting jammed in the The signal is output by the output of the circuit 1.

That is, when the external light is dark, a high signal is output at the output of the light sensing circuit 1, and when the external light is bright, a low signal is output at the output of the light sensing circuit 1.

Since the external light is dark, when the high signal is output from the light sensing circuit 1, the high signal is maintained by the positive feedback resistor R ₄ , where the high signal is the resistance R ₁₃ and the diode ( Since the high signal of the delay circuit (2) is applied to the OP amp (OP ₂ ) inverting terminal (-) input of the amplifying circuit (3) after a delay time as long as it is charged to the capacitor (C ₃ ) through D ₂ ). Since the output of the OP amplifier OP ₂ becomes low and the transistor Q is turned off, the collector of the transistor Q receives a high signal, thereby turning on the thyristor SC, which is a power control element, to load a lamp (fluorescent lamp, discharge lamp, etc.). ) Will light up.

When the external light is bright, the low signal is output from the light sensing circuit 1. At this time, is the reference voltage set to the non-inverting terminal (+) of the OP amplifier OP ₂ of the amplifying circuit 3 being the inverting terminal (-)? Since the high signal is applied to the output of the OP amplifier OP ₂ because the signal is higher than the signal, the transistor Q is turned on so that the collector of the transistor Q becomes a low signal so that the thyristor SC which is a power control element is turned off. The load is turned off.

The photoconductive device connected to the photoconductive device CD and the variable resistance VR resistor R ₁ than the reference voltage set in the OP amplifier OP ₁ non-inverting terminal (+) of the sensing circuit 1 above. When the voltage detected at (CD) increases momentarily, a high signal is output to the output of the OP amplifier OP ₁ , but this is delayed by the time constant (resistance R ₁₃ , capacitor C ₃ ) of the delay circuit 2 and then amplified. Applied to the circuit 3.

That is, if the detection of external light is not maintained for a certain time and is instantaneous, it is charged by the resistor R ₁₃ and the capacitor C ₃ of the delay circuit 2 and then through the resistor R ₆ if the high signal is not applied thereafter. Since the amplification circuit 3 does not operate by discharging, the thyristor SC is not switched to prevent flicker of the lamp under load.

As described above, the present invention outputs a high signal when it becomes dark in the light sensing circuit 1, and at this time, the delay circuit 2 is delayed for a predetermined time and then the amplification circuit 3 is operated to turn on the thyristor SC. Since the load is turned on and the light detection circuit 1 detects a bright state, the load is turned off by turning off the thyristor SC via the delay circuit 2 and the amplification circuit 3.

Therefore, the present invention enables the use of AC 110 and AC 220 as the input impedance value setting of the OP amplifier, and prevents flickering when the lamp is turned off by the operation of the delay circuit (2). It is useful to extend the life of the auto flasher and to improve the reliability of the auto flasher because the load can be turned off by contactless contact.

Claims (2)

In order to connect the AC power and to turn the load on or off according to the brightness of the external light, connect the power control thyristor (SC) through the transformer (CT) and the bridge rectifier circuits (BD ₁ , BD ₂ ), A light sensing circuit 1 for detecting light by the conductive element CD and the OP amplifier OP ₁ , and a delay circuit 2 delaying the output by the time constants of the resistor R ₁₃ and the capacitor C ₃ . Contactless, characterized in that the OP amplifier OP ₂ , the transistor Q, and the resistors R ₈ -R ₁₂ are connected to each other, and the thyristor SC can be switched through the amplification circuit 3. Photoelectric flasher. The power supply (Vcc) is output through the transformer (CT) primary side and the bridge rectifier circuit (BD ₁ ) when the load is turned off, and the transformer (CT) by the thyristor (SC) when the load is turned on. Solid-state auto flasher, characterized in that the voltage induced on the secondary side of the bridge rectifier circuit (BD ₂ ) is configured so that the power supply (Vcc) is output.