KR960001838Y1 - On-off control device for a lamp - Google Patents

Abstract

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Description

Flashing control device of dimming lamp

1 is a block diagram of a flashing control device according to the dimming lamp of the present invention

2 is an exemplary embodiment of a remote depth portion applied to the present invention

3 is an embodiment of a demodulation unit applied to the present invention

4 is an embodiment of the amplification, comparison unit applied to the present invention

5 is an embodiment of the reset unit and the lamp driving unit applied to the present invention

* Explanation of symbols for main parts of the drawings

10: reception signal processing unit 15: demodulation unit

20: DC amplifier 25: comparison unit (buffer)

30: switching unit 35: counting signal generator

40: binary counter 45a, 45b: first and second lamp driver

50: reset unit 60: power supply unit

D _{1 to} D ₅ : diodes Q _{1 to} Q ₇ : transistors

RY1, RY2: relay RY1a, RY2a: relay a contact

R _{1 to} R 28: resistance C _{1 to} O ₁₁ : capacitor

OP _{1 to} OP ₄ : Amplification and Comparator ZD: Zener Diode

PD: Light receiving element AND: End gate

The present invention relates to a dimming device (or lighting device) having a plurality of lamps, and more particularly to a dimming lamp flashing control device that can control the flashing of a plurality of lamps sequentially by generating an oscillation signal of a remote optical signal. .

In general, a dimmer used for lighting purposes of each home light is provided with at least a plurality of lamps and a lamp lighting circuit, and is provided with switching means for selectively lighting the lamp by the user through the lamp lighting circuit.

In order to solve the user's inconvenience of blinking the lamp by operating the rotary switch in such a dimmer, the improvement of the sequential blinking method by remote light transmission is being made in recent years, and the flashing control means of the light reception is various. It is designed.

For example, as described in Korean Patent Application No. 93-8072, the light receiving lamp is photoelectrically converted to control the dimming lamp by one step by program execution of the microprocessor according to the number of photoelectrically converted inputs.

However, according to the above invention, the performance of the control efficiency by applying the microprocessor can be expected, but it requires basic peripheral circuits according to the program execution of the microprocessor, and also the electric power of the corresponding lighting lamp according to the key input. In addition, the circuit configuration of the dimming blink control is not only complicated, but also economically disadvantageous, since a logic circuit for maintaining and maintaining the lamp other than the lamp corresponding to the key signal is a requirement.

Therefore, the present invention has been proposed in view of the above-described invention, and its object is to provide a flash control device for a new dimming lamp which can reduce the simple circuit configuration and economic burden by a professional method.

Specific means of the present invention for achieving the above object is a receiving unit for obtaining an oscillation frequency of a predetermined level by an optical signal of a remote location and extracting and amplifying only the AC component of the oscillation frequency to modulate an input optical signal, and in the receiving unit A demodulator for comparing the input potential generated for each modulated output signal with a reference set potential generated by the partial pressure of the feedback, detecting the corresponding output potential according to the comparison result, and extracting a lamp blinking signal; A DC amplifying unit for DC-amplifying the detection output, a buffer for generating a switching signal by comparing a DC potential of the input key signal output from the DC amplifying unit with a Zener voltage as a reference potential by constant voltage supplying the power supply B; And a switching unit generating a trigger signal only when the switching signal output from the buffer is positively spread, and the trigger of the switching unit. A counting signal generator for generating a counting pulse by generating a corresponding number of anti-glare waves each time a signal is applied, and generating a binary coded data corresponding to the number of inputs of the counting pulses, and selecting and turning on a selected lamp of the dimming lamp A binary counter for maintaining the lighting state of the light source, a dimming lamp driver for flashing and switching a single or a plurality of dimming lamps according to the coded signal output from the binary counter, and the number of input pulses counted by the binary counter And a reset circuit section for generating a reset signal each time a predetermined number of times is reached to clear the count value of the binary counter to an initial state, and a power supply section for supplying power for driving each of the functional means.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 1, a key button KY set on a light transmitter 5 of a remote place to select a desired dimming lamp while a power B required for driving each function is supplied through the power supply unit 60. When () is pressed, infrared rays having a predetermined wavelength for the dimming lamp selection command are emitted from the optical transmitter, which emits infrared rays in a number corresponding to the number of presses of the key button KY.

As described above, the transistor biasing the supply power B to the diodes D1 and D2 through the output terminal of the light receiving element PD of the receiver 10 installed in the quencher whenever infrared rays are emitted as described above. The combination of Q1, the resistor R1, and the capacitor C1 produces a predetermined pulsed oscillation frequency.

The oscillation frequency generated in this way is passed through only the AC component by the condenser C1, and the oscillation frequency of the passed AC component is amplified to a voltage of a predetermined level through the amplifier OP1.

At the same time, the demodulator 15 modulates and amplifies and outputs the potential outputted from the receiver 10 input to the non-inverting terminal (+) of the comparator OP2 as shown in FIG. The presence or absence of an output signal of the receiver 10 is detected by comparing the reference set potential generated by the partial pressure of the feedback inputted to the input signal, wherein the output potential modulated by the receiver 10 is greater than the reference potential of the comparator OP2 ( The lamp blinking signal is output only when +>-), and the lamp blinking signal extracted by this condition is demodulated by direct current through a detector composed of diodes D4 and D5.

In this case, since the DC demodulation signal output from the demodulator 15 may include an error external light that affects the lamp flickering control, the DC demodulation signal 15 may be inputted through the variable element VR of the DC amplifier 20. By adjusting and setting the output of the DC demodulation signal within a predetermined range, it is possible to reliably distinguish the operation related to the key input signal.

As such, the output of the demodulator 20 detected by the demodulator 15 and adjusted through the variable element VR is amplified to a predetermined voltage through the DC amplifier 30 again as shown in FIG. .

At this time, if the amplification output of the amplifier 20 is applied to the inverting terminal (-) of the comparator OP4 of the buffer 25, that is, if it is smaller than the reference potential of the breakdown voltage of the zener diode ZD, there is no key input or light. Since the hand is released from the key of the transmitter, the output of the comparison unit OP4 at this time becomes 'low', whereby the switching unit 30 is turned off so that the first and second lamp driving units 45a and 45b of the rear stage are turned off. Will remain off.

However, if the amplification output of the amplifier 20 is greater than the reference potential applied to the inverting terminal (-) of the comparator OP4 of the buffer 25, the output terminal of the comparator OP4 becomes 'high'.

Accordingly, the transistor Q2 of the switching unit 30 is turned on and simultaneously triggers the coefficient signal generator 35 connected to the output terminal thereof.

At this time, the coefficient signal generator 35 triggered by the on operation of the transistor Q2 of the switching unit 30 generates a corresponding number of anti-glare waves each time a trigger signal is applied from the switching unit 30. It will output the counting pulse of.

Whenever the count signal generated by the count signal generator 35 is output as described above, the binary counter 40 counters the input count pulse as shown in FIG. 5, converts it into a binary code data value, and outputs the same. The value is stored until another counting pulse is input.

At this time, if one count pulse is input to the binary counter 40 by processing the initial key input signal, the values of '0, 1' are output through the output terminals Q1 and Q2 of the binary counter 40. .

Accordingly, the transistor Q3 and the relay RY1 of the first dimming lamp driver 45a are in an inoperative state, and the transistor Q4 of the second dimming lamp driver 45b is turned on to turn on the relay RY2. Simultaneously turning on contact a of RY2a and controlling the illuminating lamp (not shown) to which AC power is applied through contact a RY2a of relay RY2 are turned on.

After that, the dimming lamp (not shown) lit by the second dimming lamp driver 45b continuously maintains the lighting state unless another counting pulse is input to the binary counter 40.

In addition, when the above-described dimming lamp (not shown) lit by the second dimming lamp driving unit 45b is turned on, pressing the key button KY of the optical transmitter 5 of FIG. Another counting pulse processed through the counting signal generator 35 is counted by the binary counter 40 and outputs a value of '1, 0' through its output stages Q1 and Q2.

Accordingly, the transistors Q4 and the relay RY2 of the second dimming lamp driver 45b by the output values Q1 = 1 and Q2 = 0 of the binary counter 40 are turned off to turn off the dimming lamps associated with them. The transistor Q3 of the first dimming lamp driver 45a, which was in the non-operating state at the same time as the start-up, is turned on to excite the relay RY1 at the output stage and simultaneously turn on the contact a of the contact point RY1a to turn on this relay RY1. Control to turn on a dimming lamp (not shown) to which an AC power source is applied through a contact RY1a of the control panel.

Thereafter, the dimming lamp (not shown), which is also lit by the first dimming lamp driver 45a, is continuously maintained unless the new counter pulse is input to the binary counter 40.

In addition, when the dimming lamp (not shown) is turned on by the first dimming lamp driver 45a and the key button KY of the optical transmitter of FIG. 1 is pressed once more, the receiving unit 10 to the counting signal generating unit ( Another counting pulse processed through 35) is counted by the binary counter 40 and outputs a value of '1, 1' through its output stages Q1 and Q2.

Accordingly, the transistors Q3 and Q4 of the first and second dimming lamp drivers 45a and 45b by the output terminals Q1 = 1 and Q2 = 1 of the binary counter 40 and the relay RY1 ( RY2 is turned on, but at this time, the output of the end gate AND, which uses the output signals Q1 and Q2 of the binary counter 40 as the input source, becomes 'high', so that the transistor Q5 of the reset circuit section 50 is turned on. , Q6 is on, and the transistor Q7 of the final output stage is turned off so that the 'high' level reset signal RS is applied to the binary counter 40 to reset its output stage (collector). .

Accordingly, the binary counter 40 turns off the first and second dimming lamp drivers 45a and 45b by clearing the previous count value and switching the output stages Q1 and Q2 to '0 and 0', respectively. At the same time, the dimming lamp corresponding to each driving unit is turned off, and waits in a state where a newly input counting pulse can be recounted.

Thereafter, if the above-described series of operations are repeated periodically, the two dimming lamps can be controlled alternately in the order of the operation description.

In this case, when the first or second dimming lamp drivers 45a and 45b alternately operate, the output of the end gate AND using the output signals Q1 and Q2 of the binary counter 40 as an input source. Is always 'low' so that the transistors Q5 and Q6 of the reset circuit section 50 are turned off and the transistor Q7 of the final output stage is turned on to reset the binary counter 40 connected to its output terminal (collector). The terminal RS is always kept at the 'low' level.

This is the function of the NAND circuit having the function of logical negation between the output of the end gate AND and the reset circuit section 50 through the bias resistor R23 in inverting the reset signal of the binary counter 40. Is done by.

As described above, the present invention amplifies and buffers modulation means for generating a predetermined oscillation frequency by an optical signal from a remote location, detection means for error prevention according to the detection of the oscillation frequency, and a DC signal obtained by a detection demodulation process. Means for generating a counting signal for each triggering signal, and means for flashing the lamps sequentially, and means for periodically resetting the flashing means, and waiting for the initial state by remote control. Simultaneous flash control can provide convenience for use, and the circuit configuration can be simplified compared to the existing lamp flasher, which can result in economical savings.

Claims (1)

The receiving unit 10 modulating the input optical signal by obtaining a predetermined level of oscillation frequency by a remote optical signal, extracting and amplifying only an AC component of the oscillation frequency by controlling a plurality of dimming lamps in three steps. And a demodulator 15 which compares an input potential generated for each output signal modulated by the receiver with a reference set potential generated by the partial pressure of the feedback, detects a corresponding output potential according to the comparison result, and extracts a lamp blinking signal. And a direct current amplifier 20 for directly amplifying the detected output extracted by the demodulator, and a Zener for constant voltage of the direct current potential of the input key signal outputted from the direct current amplifier and the power supply B. A buffer 25 for generating a switching signal by comparing voltages, a switching unit 30 for generating a trigger signal only at a constant pulse of the switching signal output from the buffer, and Each time a trigger signal of the switching unit is applied, a coefficient signal generation unit 35 for generating a corresponding number of anti-glare waves and providing coefficient pulses, and binary coded data corresponding to the number of inputs of the coefficient pulses are generated to adjust the illumination. A binary counter 40 for maintaining a selected lamp of the lamp and a lit state of the selected lamp, and first and second dimming lamps for flashing a single or a plurality of dimming lamps according to an encoded signal output from the binary counter. A reset circuit section for generating a reset signal whenever the number of inputs of the driving pulses 45a and 45b and the counting pulse counted by the binary counter 40 reaches a predetermined number of times to clear the count value of the two-counter counter to an initial state. And a power supply unit (60) for supplying power for driving each of the functional means (50).