KR930006136Y1 - Main switch circuit used for remote control - Google Patents

Abstract

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Description

Main switch control circuit using remote controller

1 is a circuit diagram of the present invention.

2 is an implementation circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

10: connection 20: SMPS power supply

30: rectification stage 40: connection switching stage

50: storage battery 60: microcomputer

70: connection driving stage 80: transmitter

90 receiver Q1 transistor

RY: Relay D1, D2: Diode

C1: condenser

The present invention relates to a main switch control circuit using a power regulator for controlling an electronic switch directly using a remote controller in an electronic device using a remote controller.

The household electronics are gradually controlling the set with a remote controller for convenience, but currently the main switch of the set does not turn on / off the remote control electronics and the standby mode is used to receive the remote control signal from the remote controller. Power consumption is high because power must be supplied continuously.

That is, the set adjustment by the remote controller was possible only when the standby power was always supplied to the micom that receives the remote control signal and outputs a control signal corresponding to the adjustment signal, and a relay that supplies the main power to the set to drive the micom.

Therefore, the electronics had to be 'off' the main switch to eliminate power consumption inside the set, but for remote control-enabled electronics it would always consume standby power, even when the set was not in operation.

As such, the electronic device using the power regulator always requires a standby power supply, and there is a inconvenience in that the user cannot turn on / off the main switch by the power regulator, and consume power by the continuous standby power supply.

In view of the above, the present invention aims to reduce power consumption and ease of use by enabling the main switch of an electronic device using a remote controller to be controlled by a remote controller. It is supplied with standby power so that the main switch can be turned on / off by the remote controller.

Hereinafter will be described in detail with reference to the accompanying drawings the configuration and effect of the present invention.

1 is a circuit diagram of the present invention, the AC input is configured to be supplied to the set operating power supply through the rectifying stage 30 through the switching mode power supply (SMPS) power stage 20, the rectifier stage ( 30 is operated by a connection switching stage 40 for selectively supplying the operating power of 30 and the charging voltage of the storage battery 50 to the microcomputer 60, and a power applied through the connection switching stage 40, The microcomputer 60 which receives a key input and outputs a main switch driving signal, the connection driving stage 70 whose operation is selected by the main switch driving signal of the microcomputer 60, and the operation of the connection driving stage 70. According to the present invention, the connection terminal 10 is configured to intercept the AS input supplied to the SMPS power supply terminal 20.

2 is an implementation circuit diagram of the present invention, wherein the connection terminal 10 is composed of a relay RY, the connection driving terminal 70 is composed of a transistor Q1, and the connection switching terminal 40 is an output of the rectifying terminal 30. And a diode (D1) (D2) for selecting the output of the battery 50 and applying it to the microcomputer 60, and the chattering prevention capacitor (C1) is connected to the cathode side of the diode (D1) (D2).

At this time, the battery 50 is charged by the operating power output from the rectifying stage 30 and the charging voltage (V2) of the battery 50 is set slightly lower than the output voltage (V1) of the rectifying stage (30) Set 60 to a voltage sufficient to cause a standby operation.

In the present invention configured as described above, the relay RY is 'off' so that AC power cannot be supplied to the SMPS power stage 20, and thus there is no power consumption in the standby state as in the prior art.

On the other hand, the standby power of the set is supplied by the charging voltage of the battery 50. The charging voltage of the battery 50 is applied to the microcomputer 60 while being applied to the relay RY through the diode D2. .

Therefore, the microcomputer 60 maintains the standby state by the charging voltage of the battery 50 and does not maintain the standby state by the AC power supply, thereby eliminating AC power consumption.

In this way, when the microcomputer 60 is 'on' the main switch of the remote controller 80 in the standby state by the charging voltage of the battery 50, it is applied to the remote control signal receiver 90 and the receiver 90 When the remote control signal received by the microcomputer 60 is applied to the microcomputer 60, the microcomputer 60 outputs a high level main switch driving signal to the base of the transistor Q1 of the connection driving terminal 70.

The transistor Q1 is 'turned on' when the high level main switch driving signal is applied from the microcomputer 60, and when the transistor Q1 is 'turned on', the relay RY to which the charging voltage of the battery 50 is applied is provided. When the relay switch is 'on' when the AC power is supplied to the SMPS power stage 20, the output power of the SMPS power stage 20 is rectified in the rectifier stage 30 is supplied to the operating power of the set.

The operating power of the rectifying stage 30 is applied to the set operating circuit and at the same time through the diode D and then to the microcomputer 60 so that the microcomputer 60 is driven by the operating power of the rectifying unit 30.

At this time, since the output voltage V1 of the rectifier 30 is set to be larger than the charging voltage V2 of the storage battery 50, when the output voltage V1 of the rectifier 30 appears, the diode D1 is 'on', but the diode D2 becomes 'off', and thus charging voltage V2 of the storage battery 50 is not applied to the operating power of the microcomputer 60, thereby preventing the charging and discharging of the storage battery 50.

And the operating power of the rectifier 30 is also supplied to the charging voltage of the battery 50, so that the operation of the battery 50 is smooth after the AC input is cut off.

At this time, when the charging voltage of the battery 50 and the output voltage of the rectifying unit 30 are switched from the diodes D1 and D2 as the operating power of the microcomputer 60, the diode D1 is prevented to prevent chattering and instantaneous power failure. Connect capacitor C1 between the cathode side of D2 and ground.

In this way, in the electronic device using the remote controller, the main switch of the electronic device is turned into a power regulator by supplying the standby power of the microcomputer using the battery and turning the main switch on by the remote control signal of the remote controller. It can be interrupted to provide convenience in use and to eliminate AC power consumption in standby mode.

Claims (3)

Remote controller for AC input through the SMPS power stage 20, rectified in the rectifier stage 30 and supplied to the operating power, and recognizes the remote control signal of the remote controller 80 in the microcomputer 60 through the receiver 90 In the electronic device used, a connection switching end 40 for selectively supplying the operating power of the rectifying stage 30 and the charging voltage of the storage battery 50 to the power of the microcomputer 60, and the main of the microcomputer 60. A remote controller comprising a connection driving stage 70 operated by a switch driving signal, and a connection stage 10 for controlling AC power input supplied to the SMPS power supply stage 20 according to the operation of the connection driving stage 70. Main switch interrupt circuit. The method of claim 1, wherein the connection switching stage 40 is a diode (D1) (D2) for selectively supplying the microcomputer 60 with the operating power of the rectifier stage 30 and the charging voltage of the battery 50, and the diode (D1) A main switch control circuit using a remote controller composed of a condenser (C1) to prevent chattering and instantaneous power failure generated during the switching operation of (D2). The main switch control circuit according to claim 2, wherein the output voltage (V1) of the rectifying stage (30) is set to be larger than the charging voltage (V2) of the storage battery (50) (V1 > V2).