KR0150157B1 - Power saving apparatus and method for vcr - Google Patents

Abstract

[Technical field to which the invention described in the claims belong]

The present invention relates to a method and apparatus for maintaining the operation of the microcomputer even if the power supply is interrupted when the video device is not used.

[Technical Challenges to Invent]

The conventional power supply circuit solves the problem of wasting power consumption because a certain amount of power is continuously supplied to the microcomputer when the video is not used.

[Remedy summary of the invention]

Provides a method of temporarily controlling the relay switch installed after the power plug to cut off the power and at the same time charging and using the backup power that only microcomputer can operate.

[Important Uses of the Invention]

Power saving device and method in a video device.

Description

Power saving device and method in a video device.

1 is a block diagram of an apparatus for saving power consumption when the power is applied to the present invention.

2 is a flow chart of power control when initial power is applied according to the present invention.

3 is a flowchart of state maintenance when power is applied to the present invention.

4 is a flow chart when a power source is switched from an on state to an off state according to the present invention.

* Explanation of symbols for main parts of the drawings

10: relay switch 20: power supply

30: microcomputer 24: initial power supply switching unit

The present invention relates to a method and apparatus for allowing the operation of the microcomputer to be maintained even if the power supply is stopped when the video device is not used.

In general, in the conventional power supply circuit, since a certain amount of power is continuously supplied to the microcomputer when the video is not used, there is a problem in that power consumption is wasted.

Accordingly, an object of the present invention is to temporarily cut off the power by controlling the relay switch installed after the power plug, and at the same time, to reduce unnecessary power consumption by leaving backup power that only the microcomputer can operate.

The present invention for achieving the above object is the first switching means for transferring the input AC power to the rear end by switching for a predetermined time when the power is initially input from the AC power input unit, and the first A power supply unit for converting the AC power transferred by the switching operation of the switching means into a stable DC power source, a control unit operating by receiving power output from the power supply unit, and connected in parallel with the first switching unit A relay switching means controlled by a control signal having a time to turn on / off the power, and a power supply to the controller when the power is turned off by charging the power supplied from the power supply when the relay switching means is turned on for a predetermined time; Characterized in that the charging means to prevent the.

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

1 is a block diagram of a power consumption saving device when the power is applied to the present invention, for switching the power for a predetermined time when the power is initially input from the AC power input unit for transferring the input AC power to the rear end The first switching means 24, the power supply unit 20 for converting the AC power delivered by the switching operation of the first switching means into a stable DC power, and receives the power output from the power supply unit 20 A control unit 30 in operation, a relay switching unit 10 connected in parallel with the first switching unit 24 and controlled by a control signal with a predetermined time from the control unit to turn on / off power, and the relay Charging means 26 which charges the power supplied from the power supply unit 20 when the switching means 10 is turned on for a predetermined time and prevents power to the control unit 30 when the power is turned off. Eojinda.

2 is a flow chart of power control when the initial power is applied according to the present invention, and a high signal is applied to the right output 1 which has driven the timer 1, and a low signal is applied to the output 1 when the timer has passed 20 seconds.

3 is a flow chart of maintaining the state when the power is applied to the present invention. When the power is driven, two timers are turned off and one hour has elapsed, the timer 1 is driven and a high signal is applied to the output 1. When 20 seconds have elapsed, apply a low signal to output 1.

4 is a flowchart when the power is switched from the on state to the off state according to the present invention, which detects whether the power is turned off when the switch detection port is in a high state, and when the power is turned off in the detection process. A high signal is applied to the output 1, and a low signal is applied to the output 1 when the power is turned on in the detection process.

Hereinafter, a block diagram of FIG. 1 will be described in detail with reference to a flowchart of FIGS. 2 to 4 applied to the present invention.

Initially, when AC power is input from the AC power input unit 40, the capacitor 16 is charged through the diode 12 and the resistor 14 through the rod 42. At this time, since the low is applied to the base input terminal of the transistor 18 during the time that the capacitor 16 is charged because it is connected between the resistor 14 and the capacitor 16, the transistor 18 is turned on and the input The supplied AC power is input to the power supply unit 20 to convert the AC into DC and stabilize the power to be output. At this time, the output power is applied to the condenser 26, the microcomputer 30 and the power switch from the load 44, respectively. At this time, the power applied to the condenser 26 is charged with backup power, and the power applied to the power switch 22 is applied to one terminal of the microcomputer 30 to detect the state of the power switch 22. . The power applied to another terminal of the microcomputer 30 operates the microcomputer 30 to apply a high signal to the output 1 32 of the microcomputer 30 to turn on the transistor 28. Therefore, the power supply through the load 44 drives the relay switch 10 connected in parallel to the transistor 18 through the transistor 28. In this case, when the control procedure of the microcomputer 30 is described with reference to the flowchart of FIG. 2, the timer 1 is driven in step 100 and the high signal is applied to the output 1 in step 110. Then, while applying the high signal to the output 1, the microcomputer 30 detects whether the timer has passed 20 seconds in step 120. Then, when the timer has passed 20 seconds, the microcomputer 30 applies a low signal to output 1 in step 130. Then, when the power is charged to the condenser for 20 seconds driving the timer and the power is turned off by cutting off the relay switch 10 applying the low signal from the microcomputer 30, the power applied to the other device is cut off. The power applied to the microcomputer 30 prevents the power stored in the capacitor so that only the microcomputer 30 supplies power for 1 hour. In addition, when 1 hour has elapsed after the front end of the microcomputer 30 is applied to the microcomputer 30, the microcomputer 30 detects whether the power is turned off in step 140. Then, the timer 2 is driven in step 150. At this time, in step 160, the microcomputer 30 detects whether the timer 2 has been driven or 1 hour. At this time, when the timer 2 has been driven for 1 hour, the timer 2 is reset in step 170 and the timer 1 is driven in step 180. Then, in step 190, a high signal is applied to output 1. At this time, the microcomputer 30 detects whether the timer has passed 20 seconds while applying the high signal to the output 1 in step 200. Then, when the timer has passed 20 seconds, the microcomputer 30 applies a low signal to output 1 in step 210. Therefore, the power applied to the microcomputer 30 is maintained by charging the capacitor 26 again for 20 seconds as described above.

If the power switch 22 is touched, the control sequence when touched is described with reference to FIG. 4. First, in step 220, the microcomputer 30 detects whether the switch detection port is in a high state.

In this case, in step 230, the microcomputer 30 detects whether the power is off. Then, in step 240, when the power is off, the microcomputer 30 applies a high signal to the output 1 in step 240, but when the power is on in step 230, the microcomputer 30 outputs a low signal to the output 1. Apply. In this case, when the high signal is applied to the output 1, the relay switch 10 is turned on and power is supplied to other devices. When the low signal is applied to the output 1, the relay switch 10 is turned off. Power to other devices is cut off.

As described above, the present invention provides a method by temporarily controlling a relay switch installed after a power plug to cut off the power and at the same time charging and using a backup power that only a microcomputer can operate. There is an advantage in eliminating unnecessary power consumption of the device.

Claims (5)

A power saving device in a video device, comprising: first switching means for transferring a predetermined amount of AC power to a rear end by switching for a predetermined time when power is initially input from an AC power input unit, and the first switching means Power supply means for converting the AC power transferred by the switching operation into a stable DC power, control means for receiving and operating the power output from the power supply means, and the control means connected in parallel with the first switching means Relay switching means for turning on / off the power by being controlled by a control signal having a predetermined time from the power supply; and when the relay switching means turns on for a predetermined time, the power is turned off by charging the power supplied from the power supply means. In the video device, characterized in that consisting of a charging means for preventing power to the control means when Power consumption. The apparatus of claim 1, wherein the first switching means connects a transistor and a capacitor in parallel to transfer initial power input by operating the transistor during a charging time of the capacitor. In a video device including a relay switching means, a microcomputer, a power supply means, an initial switching means, and a charging means, a method of saving power consumption by controlling power when initial power is applied, and when the AC power is initially input, goes backward for a predetermined time. An initial switching process of switching operation to deliver the input AC power, a power supply process of converting and outputting AC power delivered by the initial switching process into a stable DC power, and power supplied from the power supply means Generating a control signal for a predetermined time for turning on the relay switching means connected in parallel to the initial switching means through an input from a microcomputer, and the relay switching means is turned on by the generated control signal; Charging process in which the supplied AC power is charged to the charging means via the power supply means And generating a power off signal from the microcomputer to turn off the relay switching means, and discharging the charged power through the charging process to supply power to the microcomputer. How to save power consumption by controlling power. The method of claim 3, wherein the charging process is performed by charging power for 20 seconds to supply power to the microcomputer for 1 hour. The method according to claim 3 or 4, wherein after the one hour has elapsed, a control signal for turning on the relay switching means is generated from the microcomputer to the output 1 so that the power is charged to the charging means again. How to save power by controlling power when initial power is applied from video device.