KR940002419B1 - Remote control powersupply and data communication circuit by infrared rays - Google Patents

Abstract

A power line PLC remote controlling power supply and data communication circuit using infrared rays includes a power source for dropping and rectifying AC power and converting it into a plurality of DC, a relay for controlling power supply to a load, a MODEM for transmitting transmission/received data after modulation or demodulation, an infrared ray receiver for receiving a remote infrared signal, a zero-crossing detector for detecting a zero crossing point, a CPU, a relay set/reset circuit for generating a set/reset signal for turning on/off of the relay, and a relay detector for detecting the turning on/off state of the relay, thereby easily converting AC into DC.

Description

Power line carrier remote control power supply and data communication circuit using infrared rays

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

The present invention relates to a remote control device, and in particular, supplies power without using a transformer, but uses a infrared light receiver and a carrier type (PLC) method to cut off power to a remote control remote control, and transmits a signal with a main device using a power line. The present invention relates to a power line carrier remote control power supply and data communication circuit using infrared rays.

In general, the range of using the infrared remote control is wide, such as home appliances and industrial equipment. All of these provide convenience by selecting the desired function of the system from a remote control by remote control signals.

FIG. 1 is a Korean Utility Model Publication No. 88-1575, which is a "remote control device for lighting" published on March 15, 1988. The relay switch (S y) is connected to one of the power lines (L1, L2) of the lamp (1). ), One end of the relay (Ry) winding thereof is connected to the output terminal of the constant voltage circuit (2) and connected to the base of the transistor (Q2) through the resistor (R1) and the switch (SW), and the relay (Ry) The other end is connected to the collector of the emitter ground transistors Q1 and Q2, and the base of the transistor Q1 is configured to be connected to the cathode of the diode D1 connected to the output terminal of the remote control receiver 3.

That is, the infrared remote control 4 is used to directly turn on / off the relay Ry through the remote controller receiver 3, thereby controlling the lamp 1 to be turned on / off, but using a voltage drop using a transformer as a power source. It is supposed to be supplied.

In FIG. 1, the power supply control receives a signal from the infrared remote controller 4 and turns on and off the relay Ry using the transistor Q1, and drops the voltage using the transformer for the internal power supply and then rectifies the circuit 2. DC power is supplied through), and the relay Ry is driven by receiving a signal from the remote controller receiver 4 and driving the transistor Q1 through the diode D1. The relay Ry is turned on and off in the same manner by pressing the manual switch SW.

However, the conventional method described above has a drawback in that the DC power is supplied using a transformer even when a circuit with low current consumption is expensive, and the remote control for simple control without using a CPU is expensive.

Therefore, the object of the present invention is to operate the circuit by simply constructing the circuit without using a transformer in a small, small current circuit, and supplying and cutting off the power by remote control remote control using infrared light receiving unit and PLC method, The present invention provides a circuit for transmitting a signal with a main device.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

2 is a circuit diagram according to the present invention, connected to the AC power line is connected to the AC power drop through the coil (L), capacitor (C1), resistor (R1), rectified through the bridge diode (BD) A power supply unit 10 for converting the regulators RG1 and RG2 into DC, a relay RLY1 for controlling power supply to the load LD, a capacitor C5, a transformer T1, An infrared light receiving unit 30 configured to receive a remote infrared signal composed of a modem unit 20 for modulating and transmitting and demodulating and transmitting / receiving data through a modem, and a resistor (R2, R3), a capacitor (C6), and an infrared receiver (RCV). And a zero crossing detection circuit 21 connected to the AC power line and detecting a zero crossing point, and transmitting and receiving data through the modem unit 20 to receive a remote signal received through the infrared light receiving unit 30. Processing to generate an on / off control signal of the relay RLY1, A central processing unit (CPU) for detecting an operation state, and a relay set / reset circuit (RS) connected to the central processing unit (CPU) to generate a set / reset signal for on / off of the relay (RLY1) , RR, and a relay state sensing circuit 22 that senses an on / off state of the relay RLY1 and provides the CPU.

Therefore, when a specific embodiment of the present invention will be described in detail with reference to FIG. 2, the power supply unit 10 uses a resistor R1, a capacitor C1, and a coil L to supply DC power through the bridge diode BD. It is supplied, but is divided into 12V, 5V through the regulator (RG1, RG2). The coil (L) serves to protect the driving state during the initial power input. That is, since the power input initial coil L is in an off state, the instantaneous current is blocked, and thus, the transient current can be prevented. In addition, it is possible to increase the noise level by increasing the value of the coil (L) to play an important role in the removal of high frequency components.

Since the capacitor C1 is about to be shorted at the initial power input, a momentary high voltage may be applied to the capacitor C2.

The zener diode ZD1 is used for the purpose of preventing the voltage from rising to such a high voltage, thereby protecting it from rising above a certain voltage. in Therefore, when a large amount of current flows in the instantaneous time change, if the capacity of the capacitor C2 is large, ΔV becomes small, and therefore the capacitor C2 uses a large value.

In order to prevent the high current of the AC power supply from being input to the circuit and adversely affecting the circuit when the initial capacitor C1 is short, the current flowing in the instant is limited by using the resistor R1 value.

If the capacitor (C1) is about 1㎌, Zc1 = 1JΩ, and if the capacitor (C1) capacity is large, Zc2 will be lowered to a few 므로. do.

Therefore, the capacitor C1 should use a large internal pressure. For ZL = 2 π fL, the value of = 0.3Ω is also used for severalΩ. The voltage output through the zener diode ZD1 is output 12V through the regulator RG1, and is then input to the regulator RG2 to output the 5V output voltage. Since the current flowing due to the capacity limit of the resistor R1, capacitor C1, and coil L does not flow more than 200 mA, it is a useful method when the current used in the internal circuit is small. The infrared receiver 30 including the resistors R2 and R3, the capacitor C6, and the infrared receiver RCV supplies a constant voltage to the infrared receiver RCV by the resistor R3 and the capacitor C6. R2) to keep the output pulled up.

When the remote control signal is received, the received signal is applied to the central processing unit (CPU), and the central processing unit (CPU) performs the relay RLY1 on and off operations. The central processing unit (CPU) is an i8051 series in which a capacitor C7 and a resistor R4 are connected by a reset circuit.

The output signal of the font P0.1 is sent to the relay set circuit RS to turn on the relay RLY1, and the font P0.1 is sent to the relay reset circuit RR to send the relay RLY1. Make it off. When the relay RLY1 is turned on, AC power is supplied to the load LD. The relay state sensing circuit 22 is formed on the load LD that has passed through the relay Ry1 to check the current state of the relay RLY1 on and off to inform the CPU of the current state. When the current state of the relay RLY1 is known to the CPU, the CPU is in data communication with the host device via the modem. Modem transmits and receives 125㎑ signal and converts analog signal and digital signal to AC terminal.

The capacitor C5 and the transformer T1 remove the low frequency component of 60 Hz and act as a filter for passing only the 125 KHz component. The zero crossing detection circuit 21 is connected to the central processing unit (CPU) to indicate the starting point of signal transmission when the power goes up by 0.7V using the 60㎐ power supply to inform the data to be started when the data is communicated with the main unit. .

As described above, in the case of a circuit having low current consumption, an AC power source can be simply made into a DC power source without using an expensive transformer, and there is an advantage of making a constant output DC voltage with respect to the AC input power source. In addition, the relay can be turned on and off using an infrared receiver and data communication can be performed using a power line.

Claims (3)

In the remote control power supply and data communication circuit, a power supply unit 10 connected to an AC power line for dropping and rectifying AC power and converting the AC power into a plurality of DCs, and a relay for controlling power supply to the load LD ( RLY1), a modem unit 20 connected to the AC power line to modulate and transmit and receive data, an infrared light receiving unit 30 to receive a remote infrared signal, and a AC crossover line to detect a zero crossing point. It transmits and receives data through the zero crossing detection circuit 21 and the modem unit 20, processes the remote signal received through the infrared light receiving unit 30, and generates an on / off control signal of the relay RLY1. A relay set for detecting an operation state of the relay RLY1 and a relay set connected to the central processing unit CPU to generate a set reset signal for turning on / off the relay RLY1; Reset time (RS, RR) and a relay state sensing circuit 22 for sensing the on / off state of the relay (RLY1) and providing it to the CPU (CPU), power line carrier remote control using infrared rays Power supply and data communication circuits. The method of claim 1, wherein the power supply unit 10 is connected to the AC power line is connected to drop the AC power through the coil (L), capacitor (C1), resistor (R1) and rectified through the bridge diode (BD) Power line carrier remote control power supply and data communication circuit using infrared rays, characterized in that the regulator (RG1, RG2) is converted to DC. The power line carrier type remote control using infrared rays of claim 1, wherein a modem unit 20 is connected to the AC power line to modulate and demodulate transmit and receive data through a capacitor C5, a transformer T1, and a modem. Control power supply and data communication circuits.