KR0164950B1 - Degaussing circuit of image display apparatus - Google Patents

Abstract

In the present invention, in the device circuit in the power-off or power saving mode, the relay must be turned on to reduce the loss of the device circuit, so that the power consumption requirements in the power saving mode can be satisfied. A device circuit of an image display device.

In the device circuit of the conventional video display device, the relay is turned on in the power saving mode because a large heat loss occurs in PTC and the device coil when the relay is turned off, so that the relay is turned on even in the power saving mode. As a result, heat loss of the PTC and the device coil can be prevented. However, due to the operation of the relay, there is a problem in that it is difficult to satisfy the specifications required in the power saving mode.

In order to solve the conventional problems, the present invention configures a main power supply and an auxiliary power supply, and configures a relay that is dependent on the main power supply, so that the power supply of the relay controlling the operation of the element coil is cut off in the power saving mode. In addition to the protection of the device coil, and to prevent the power loss due to the operation of the relay in the power saving mode, it is possible to easily meet the power saving mode specifications.

Description

Device Circuit of Image Display Equipment

In the present invention, in the device circuit in the power-off or power saving mode, the relay must be turned on to reduce the loss of the device circuit, so that the power consumption requirements in the power saving mode can be satisfied. A device circuit of an image display device.

As shown in FIG. 1, the element circuit of the conventional image display device includes a line filter unit 1 which is composed of coils L1 and L2 and a capacitor C1 to line filter the AC power input thereto. ), A bridge diode BD1 for bridge rectifying the AC power output through the inrush current preventing resistor R1, the line filter unit 1, and the power rectified by the bridge diode BD1 are supplied to supply power. The main power supply unit 2 to be switched on, the transistor Q1 to be switched on / off according to whether the device signal is input, the relay RL1 to be switched in accordance with the on / off switching of the transistor Q1, and the relay RL1. PTC (3) for changing the resistance value by the current applied in accordance with the switching of) and the element coil (L3) for generating the device current by receiving the current applied from the PTC (3).

Reference numerals C2 and C3 are capacitors.

In the device circuit of the conventional video display device configured as described above, when the relay RL1 is turned off, the terminals of the relay RL1 are connected to P0 and P1, and the AC power input when the power is turned on is switched by the switching of the relay RL1. It is applied to (3), and is applied to element coil L3 through PTC 3 so that element current flows, and the CRT element is made to element.

At this time, the PTC (3) is a device that the temperature rises as the current flows, the resistance value increases as the temperature rises.

That is, in the above device operation process, as shown in FIG. 2, when the power is turned on, the device signal is automatically input to the base of the transistor Q1, that is, 'F1' shown in the drawing, to operate the device coil. (t1), and then high is input again to turn on the transistor Q1, so that the relay RL1 is ounce-positioned so that P0 and P2 are contacted, thereby ending device operation.

Then, when the viewer manually inputs the device signal while using the TV, as described above, a low is inputted to the base of the transistor Q1 and the transistor Q1 is turned off, and thus the relay RL1 is turned off, thereby the device coil. (L3) is operated (t1).

Here, in the normal operation after the device operation is completed, the terminals of the relay RL1 are connected to P0 and P2 to reduce the loss caused by the inrush current preventing resistor R1.

In addition, when the power saving mode signal is input to operate in the power saving mode, the signal F1 input to the base of the transistor Q1 is kept in a high state. Accordingly, the relay RL1 is kept in an on state, so that the contact point of the terminal is P0 and P2 remain in contact.

The reason why the relay RL1 is turned on in the power saving mode is that when the relay RL1 is turned off, a large heat loss occurs in the PTC 3 and the element coil L3 while the terminals P0 and P1 are connected. Because.

Therefore, in the device circuit of the conventional video display device, the relay RL1 is turned on even in the power saving mode, so that the heat loss of the PTC 3 and the device coil L3 can be prevented. Because of the operation, there was a problem that it is difficult to meet the necessary specifications during power saving mode.

In order to solve the conventional problems, the present invention configures a main power supply and an auxiliary power supply, and configures a relay that is dependent on the main power supply, so that the power supply of the relay controlling the operation of the element coil is cut off in the power saving mode. The operation of all relays is turned off to prevent power loss caused by turning on the relays in the power saving mode.

1 is a device circuit diagram of a conventional video display device.

2 is a waveform diagram of an element signal in an element circuit of a conventional video display device.

3 is a device circuit diagram of an image display device of the present invention.

4 is a view illustrating a device circuit of an image display device of the present invention.

a is a waveform diagram showing device signals applied from a microcomputer;

b is a waveform diagram showing the dependent signal of the main power supply.

* Explanation of symbols for main parts of the drawings

11 line filter unit 12 main power unit

13: sub power supply 14: PTC

Referring to the configuration of the device circuit of the image display device according to the present invention, as shown in FIG. 3, the line filter unit 11, which is composed of coils L11 and L12 and a capacitor C11, performs line filtering on the input AC power. And supplying power by receiving the inrush current preventing resistors R11 and R12, the bridge diode BD11 for bridge rectifying the AC power output through the line filter unit 11, and the rectified power from the bridge diode BD11. To the main power supply unit 12, the sub power supply unit 13 to supply the auxiliary power when the main power is off, the transistor Q11 to be switched on and off by a signal applied from the microcomputer, and the switching of the transistor Q11. A device current is generated by receiving a relay RL11 to be operated along with it, a PTC 14 which changes a resistance value by a current applied according to switching of the relay RL11, and a current applied from the PTC 14. The element coil L3 and the main power source A transistor Q12 that is turned on / off by a voltage supplied from (12) to control the operation of the relay RL12, and controls a voltage output from the PTC 14 and applied to the element coil 13; It consists of a relay RL12.

Reference numerals R11 to R16 denote resistors, C11 to C13 denote capacitors, D11 and D12 denote diodes, and ZD11 denotes zener diodes.

The operation of the element circuit of the video display device according to the present invention described above will be described with reference to FIG. 4. Before the power is input, the switch terminals P0 and P1 of the relay RL11 are connected to the b terminal and the relay ( RL12 is off in the off state.

In this state, the relays RL11 and RL12 are connected. When the power is turned on in this state, the AC power rectified through the bridge diode BD11 through the resistors R11 and R12 is connected to the main power supply 12. The main power supply unit 12 is applied to supply a voltage of 12V.

The voltage of 12 V supplied from the main power supply unit 12 is divided by the resistors R15 and R16 and charged in the capacitor C13.

Thereafter, as described above, after a time delay (t2) during charging of the capacitor C13, the transistor Q12 is turned on to operate the relay RL12 so that the switch terminal is connected.

That is, the relay RL12 is operated after being delayed by the charging time t2 of the capacitor C13.

At this time, since the microcomputer turns off the transistor Q11 to perform the device process for a predetermined time t1 + t2 even when the power is turned on, the relay RL11 is connected to the switch terminal in the same way as the power-off. The element current is generated in the element coil L13 by the voltage applied through 14) to perform the element operation for a predetermined time t1.

When the device operation is completed, the microcomputer operates the relay RL11 by ounce switching the transistor Q11.

Then, the switch terminals of the relay RL11 are connected to a with P0 and P1 to block the device current generated from the device coil L13 so that a normal power supply operation is performed.

Here, when the power saving mode signal is input, the power supply to the main power supply unit 12 is stopped, only the sub power supply unit 13 is operated, and the relay RL12 is operated during the discharge time t3 of the capacitor C13. When the discharge of the capacitor C13 is completed, the relay RL12 is turned off.

In addition, the microcomputer delays the transistor Q11 for a predetermined time t4 and then outputs a low signal to turn off the relay RL11.

In this case, the delay of the relay RL11 after the delay for a predetermined time t4 in the micom is to turn off the relay RL11 after the relay RL12 is turned off in order to prevent a transient phenomenon. to be.

After that, when the power saving mode is turned off, the same operation as the initial power-on is performed. When the viewer inputs the device signal manually, only the F11 signal output from the microcomputer outputs the low signal during the time (t1) of the device progressing and relay (RL11) will be activated.

As described above, the device coil protection relay is configured to protect the device coil even when all the relays are turned off in the power saving mode, thereby preventing power loss due to the operation of the relay in the power saving mode. The effect is that the specification can be satisfied.

Claims (1)

Element means for performing element operation at the time of initial power supply or at the choice of the viewer, and switching operation to supply AC input power to the element means to supply the AC input power to the main power supply means during normal operation. Including the inrush current preventing means for supplying AC input power to the main power supply means while preventing the inrush current when the initial AC power is applied in parallel to the relay and the terminal contact of the relay, the main power supply means, and the sub-power supply means And a device circuit of a video display device capable of executing a power saving mode in which a main power supply is interrupted and a sub power supply is executed, the device being input through the relay by determining a connection and a short circuit of an operation power input terminal of the device means. A relay configured by the second switching means to interrupt the path of the AC input power to the means, and the main power supply Switching means for controlling the switching operation of the relay by switching according to the level of the power output from the stage, and switching according to the control signal output from the control means to supply AC power to the element means or the main power supply means. Switching means for controlling the operation of the relay to determine, and after the element operation of the element means completes the operation of the relay to enable the normal operation of the video display device, and after a certain time has passed after the power saving mode is started And control means for outputting a control signal to the switching means to operate in an off state.