KR970001700Y1 - Remote-control lighting lamp circuit - Google Patents

Abstract

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Description

Remote lighting circuit of triac lighting

1 is a circuit diagram showing a preferred embodiment of the present invention.

2 is a block diagram of a circuit of the present invention.

* Explanation of symbols for main parts of the drawings

a: power supply b: control rectifier

c: constant voltage circuit unit d: receiving unit

e: Data processing unit f: C-MOS division circuit

g: Dimming circuit part h: Zero voltage switch part

i: EMI filter circuit part S1, S2: Power connection terminal

Q1: Diaak Q2: Triac

Q3, Q4, Q5: Transistor C6: AC Capacitor

C9, C21: Electrolytic capacitors D1 to D4: Rectifier diodes

D5, D7: bridge rectifiers R1 to R5: resistors

R7, R10 to R14: Variable resistor U2: Optical receiving module

IC1, IC2: Direct Hi PC1-PC3: Photocoupler

[Purpose of designation]

The present invention enables to remotely flash the lights installed and used in the living room of a home, such as a living room, and to control the brightness of the lights. Will be increased.

[Technical field and technical field to which the design belongs]

Conventionally, the lighting (eg, incandescent, fluorescent, etc.) to be flickering operation mainly by manual operation, when the switch is relatively far away, the user must move directly to the switch installation position, so the inconvenience of flashing operation and the lighting Many uneconomical shortcomings have been followed, including the fact that people often sleep on and waste unnecessary power.

[Technical Challenges to be Done]

The present invention is to improve the manual operation of the lamp as described above, and to provide a stable and economical lamp lighting device of the remote lighting method to increase the convenience of use.

[Configuration and Action of Design]

1 is a circuit diagram showing a preferred embodiment of the present invention, Figure 2 is a block diagram of the circuit of the present invention, respectively, the present invention is a power supply (a), a control rectifier (b), a constant voltage circuit (c), a receiver (d), a data processing section (e), a C-MOS division circuit section (f), a dimming circuit section (g), a zero voltage circuit section (h), and an EMI filter circuit section (i).

The power supply unit (a) is composed of wiring terminals S1 and S2 that can be disposed by the same wiring method as a general home built-in switch, and each terminal S1 and S2 has no polarity and is wired as it is instead of a household switch. do.

The control rectifier b is a circuit for rectifying and smoothing the switching pulse wave generated by the 'ON' operation of the triac Q2 of the zero voltage switch unit h, which is generated in the zero voltage switch unit h. The switching pulse wave of the triac Q2 is applied to the bridge rectifier D7 through the AC capacitor C6.

The switching pulse wave rectified by the bridge rectifier D7 is smoothed by the electrolytic capacitor C21, and the voltage smoothed by the electrolytic capacitor C21 is supplied to the constant voltage circuit part c.

The control rectifier (b) is connected to the constant voltage circuit (c) to generate a power supply voltage of the circuit of the present invention.

When the triac Q2 of the zero voltage switch unit h is 'OFF', a voltage of AC220V 60Hz is applied between the AC capacitor C6 and the bridge rectifier D7.

At this time, the AC capacitor (C6) has an impedance to the voltage of AC220V 60Hz, thereby acting as a resistor to lower the voltage of AC220V 60Hz below a certain voltage.

The AC voltage formed below the predetermined voltage is rectified by the bridge rectifier D7, smoothed by the electrolytic capacitor C6, and transferred to the constant voltage circuit unit c.

Meanwhile, in the constant voltage circuit part c, the rectified and smoothed switching pulses are converted into a stabilized voltage and supplied to each circuit. First, a constant voltage is applied to the base of the transistor Q3 by the resistor R5.

As a result, the transistor Q3 is in an 'ON' state, and thus the transistor Q4 is also in an 'ON' state.

As the transistor Q4 is turned on, a constant voltage is formed across the electrolytic capacitor C9 and the variable resistor R7.

The formed voltage is distributed by the variable resistor R7 and supplied to the base of the transistor Q5.

When the voltage applied to the base of the transistor Q5 is equal to or higher than the threshold voltage (the operating voltage of the semiconductor) of the transistor Q5, the transistor Q5 is turned into an 'ON' state, whereby the base current of the transistor Q3 rapidly increases. Will fall.

As a result, as the base current drops sharply, the transistor Q3 is in an 'OFF' state, and the transistor Q4 is also in an 'OFF' state because the base current is not supplied.

Accordingly, the voltage drops rapidly across both ends of the variable resistor R7. Accordingly, the transistor Q5 is in an 'OFF' state due to a lack of a base current, and the transistor Q3 is in an 'OFF' state. Q4 is again in an 'ON' state and a voltage is applied to the variable resistor R7 again.

While repeating the above process, a constant voltage is maintained at both ends of the variable resistor (R7), and a substantially constant and stable voltage is formed at both ends of the variable resistor (R7) by the cycle of the process, and the voltage is formed in each circuit unit. It is used as the power supply voltage.

On the other hand, the receiving unit (d) receives the modulated optical signal from the infrared remote control, the modulated signal coded by the remote control is received by the optical receiving module (U2) in the infrared.

At this time, the signal from the remote control is a coded pulse signal.

In the optical receiving module U2, the above-described optical signal is converted into an electrical signal, and the signal converted and coded as described above is transferred to the data processor e.

The data processor e receives a signal from the receiver d and generates an output suitable for the coded signal.

In other words, by using the conventional IC2 dedicated infrared reception circuit (IC2), the coded signal is decoded to generate an output pulse of a predetermined time on the output pin, and a manual button switch is installed to allow the user to manually operate it. To do it.

The C-MOS frequency divider circuit f, which is composed of a decimal counter circuit, comprises an output pin (10 output pins) of the integrated circuit IC2 at each pulse input by the output pulse from the data processor e. Move the 'HIGH' signal.

For example, when a pulse of a predetermined time is input from the data processor e, the output of the integrated circuit IC2 of the C-MOS frequency divider circuit f is from pin 2 to pin 3 HIGH and pin 2 HIGH. ), Pin 3 (LOW) → Pin 2 (LOW), Pin 3 (HIGH), and the rest of the output pins all move to LOW state.

The signal output from the C-MOS frequency division circuit unit f is transferred to the dimming circuit unit g via a diode connected to each pin of the integrated circuit IC2.

The dimming circuit section g generates five currents to be transmitted to the photocouplers PC1 to PC3 of the zero voltage switch section h in accordance with the output signal from the C-MOS frequency divider circuit f. A photocoupler (PC1) of the zero voltage switch unit (h) is formed of a volume resistor and connects a variable resistor to a cathode of a diode connected to each output pin of the C-MOS divider circuit (f) to vary the resistance value for each variable resistor. The current value flowing to the LED side of ˜PC3) is adjusted.

As a result, the current flowing to the phototransistor (bridge rectifier D5 side) side of the photocouplers PC1 to PC3 is also controlled.

(Photocouplers PC1 to PC3 have the characteristic of transmitting signals as electrical energy as light energy.)

On the other hand, in the zero voltage switch unit h, the power connected to the terminals S1 and S2 is applied to both ends of the triac Q2, and the signal transmitted from the data processing unit e is the photocoupler PC1 to PC3. It is transmitted to the bridge rectifier (D5) through which to adjust the diaak (Q1).

First, when the signal of the LED side (dimming circuit side) of the photocouplers PC1 to PC3 is 'HIGH', a current flows to the phototransistor (bridge rectifier D5 side) side of the photocouplers PC1 to PC3. The bridge rectifier D5 forms a closed circuit, and a constant voltage is applied to the diaak Q1.

Accordingly, the diaak Q1 is in an 'ON' state due to its own characteristic, and thus, a constant voltage is also formed at the gate of the triac Q2.

As a result, a predetermined voltage is applied to the gate of the triac Q2, so that the triac Q2 also becomes 'ON'.

As the triac Q2 is in an 'ON' state, a closed circuit is formed between the terminals S1↔S2 to operate as if the switch is closed.

On the contrary, when the signal from the dimming circuit part g becomes 'LOW' state, both ends of the bridge rectifier D5 are open circuits, and thus no constant voltage is formed in the diac Q1.

Eventually, the triac Q2 becomes an open circuit, and an open circuit is formed between the terminals S1↔S2, as if the switch was opened.

As described above, the zero voltage switch unit h performs an ON / OFF operation like a general switch.

At this time, the ON / OFF state of the triac Q2 is determined by the diac Q1, and the triac Q2 is also turned ON / OFF according to the ON / OFF state of the diaac Q1.

The trigger (threshold) voltage, which is turned on, varies according to the voltage and current applied to the diaak Q1 due to the characteristics of the diaak Q1.

As a result, the trigger voltage of the diaak Q1 varies depending on the current value transmitted from the dimming circuit part G to the LEDs of the photocouplers PC1 to PC3.

As a result, the diaak Q1 enables phase control of the triac Q2.

Here, the phase control means that the voltage is transmitted to the load side by changing the voltage at the time when the triac (Q2) is turned on at the rising (+) time or the falling (-time) of the power input (AC220V 60 Hz) between the S1↔S2 terminals. By controlling the power, the way of controlling the amount of power used by the load is controlled.

Here, when the triac Q2 performs the ON / OFF operation, a transient timing impulse voltage is generated and absorbed by the surge absorber circuit by the resistor R2 and the AC capacitor C3.

In addition, the circuit composed of rectification diodes D1 to D4 and resistors R3 and R4 serves to stably maintain the voltage transmitted to the diaak Q1 at the time of circuit driving.

When the bridge rectifier D5 is an open circuit, a voltage of about 0.7 V is applied to the diaak Q1. This prevents incomplete operation in the 'OFF' state of the diaak Q1, increasing the reliability of the circuit.

The filter circuit i composed of the resistor R1 and the AC capacitors C1 and C2 constitutes an EMI filter circuit i for reducing switching noise during the switching operation of the triac Q2.

[Effect of design]

As described in detail above, the present invention replaces the conventional switch operability of directly blinking by the user at the position where the switch is installed, so that the blinking operation can be performed remotely by using an infrared remote controller. It is possible to obtain various advantages such as being able to adjust the brightness, and the expected effect is extremely excellent.

Claims (1)

A receiver (d) for receiving a modulated optical signal from an infrared remote controller, a data processor (e) for receiving a signal from the receiver (d) and generating an output corresponding to the coded signal, and an output from the C-MOS frequency divider circuit (g) In a remote lighting circuit such as a known triac lighting system having a dimming circuit section g for generating a current to be transmitted to the photocouplers PC1 to PC3 of the zero voltage switch section h in accordance with a signal, zero The control rectifier b for rectifying and smoothing the switching pulse wave generated by the ON operation of the triac Q2 of the voltage switch part h, and the resistor R5 are applied to the transistors Q3 and Q4. A constant voltage is supplied to form a constant voltage across the electrolytic capacitor C9 and the variable resistor R7. The voltage is supplied to the base of the transistor Q5 by the variable resistor R7. Rectified, Smoothed Switching Pulse Waves It consists of a constant voltage circuit part (C) to make a stable voltage and supplies it to each circuit part, and a decimal counter circuit, and the output pin of the integrated circuit (IC2) at each pulse input by the output pulse from the data processing part (e). The C-MOS frequency division circuit f for moving HIGH 'and the signal transmitted from the data processing unit e are transmitted to the bridge rectifier D5 through the photocouplers PC1 to PC3, and the diaak Q1 and tri A remote lighting circuit of a triac lamp, characterized in that the zero voltage switch unit (h) is configured to enable the on / off switch operation of the lamp by turning the evil (Q2) on and off.