KR100326561B1 - Automatic Degaussing Circuit of Television - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic element circuit of a television capable of automatically performing element operations when the source of the television is turned on.

The automatic element circuit of the television of the present invention comprises an element coil for generating an alternating magnetic field by an input AC power supply and a current limiting resistor for limiting current in the element coil in series with the element coil to perform an element. A device for shorting a current when a current is input, a relay for blocking a current applied to the device, and a transistor for driving the relay by an input DC power supply. A switch circuit for blocking after a predetermined device time, a current limiting resistor and a time constant circuit of the device section are configured, and the device time of the device section is determined by the time constant, and the input AC power source is a DC power source. And a rectifying and smoothing circuit for converting and supplying the control terminal to the control terminal of the transistor.

According to the present invention, since there is no heat generating component as in the related art, not only can the safety of the TV set be secured, but also the device time can be arbitrarily adjusted by the time constant of the device portion and the rectification and smoothing circuit connected in series, and the device circuit is removed. The relay drive unit for the time constant circuit is also able to adjust the drive time arbitrarily.

Description

Automatic Degaussing Circuit of Television

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a degaussing circuit of a television (hereinafter referred to as "TV"), and more particularly, to an automatic device circuit of a TV capable of automatically performing device operation when a TV is turned on.

As a TV receiving tube, a cathode ray tube (CRT) is usually adopted. The cathode ray tube includes an electron gun for generating an electron beam, a deflection coil and a deflection yoke for deflecting an electron beam generated from the electron gun, a phosphor for emitting visible light of a unique color by collision of electrons, and a shadow mask for guiding the electron beam to the phosphor. (Shadow Mask). Here, the shadow mask has a property of being magnetized in the direction of Earth Magnetism determined according to the position where the TV set is installed as a metal plate. However, when the shadow mask is magnetized, the electron beam is deflected to cause color bleeding on the screen, thereby degrading image quality. In order to solve this problem, TVs are using shadow masks.

Referring to Fig. 1, a device circuit of a conventional TV is shown.

The device circuit of the TV shown in FIG. 1 includes a device part 2 composed of a PTC thermistor (PTC thermistor) and a device coil L, and a relay drive circuit 3 for operating the device part 1. And a power supply circuit 4 for supplying DC power at a level suitable for the TV circuit 6, including a rectification and smoothing circuit 2, and a microcomputer 5 for applying a driving signal to the relay driving circuit 3; Is configured. In FIG. 1, the element part 1 is connected in parallel with the rectification and smoothing circuit 2. As shown in FIG. The relay driving circuit 3 is composed of a relay RE for driving the relay switch RS of the element unit 1 and a transistor Q for driving the relay RE. The transistor Q is turned on / off in accordance with the drive signal input from the microcomputer 5. When a high driving signal is applied from the microcomputer 5, the transistor Q is turned on to drive the relay RE. The element part 2 is connected in series between the first power supply line 7 and the second power supply line 8 by turning on the relay switch RS by the driving of the relay RE. In the initial stage when AC power is input through the first and second power lines 7 and 8, the resistance value of the PTC thermistor (PTC) is low so that a large amount of current flows in the device coil L, thereby forming a device of a shadow mask. . As the resistance increases infinity due to the exothermic action of the PTC thermistor (PTC) over time, the current applied to the device coil (L) no longer flows and the device is terminated. In this case, when power is continuously applied to the device unit 1, there is a problem in that image quality is degraded due to a current leaking from the PTC thermistor PTC. To prevent this, the microcomputer 5 opens the device unit 1 by turning off the relay switch RS by applying a driving signal in a low state to the transistor Q at the end of the device time.

However, the element circuit of the above-described configuration carries a risk of fire because the PTC thermistor (PTC) changes the resistance value depending on heat generation irrespective of the operation of the TV. In addition, in the conventional device circuit, since the device time is limited to the heat generation time of the PTC thermistor (PTC), there is a disadvantage in that arbitrary time adjustment is almost impossible. In addition, since the driving circuit 3 for operating the device circuit unit 2 needs to be controlled using the microcomputer 5, a separate program and a port for the device are required, so that the load of the microcomputer 5 is large.

Accordingly, it is an object of the present invention to provide an automatic element circuit of a TV which can secure the safety of a TV set by removing heat generating parts.

Another object of the present invention is to provide an automatic element circuit of a TV that can reduce the cost and control the element time by using the rectifier circuit included in the power supply circuit as part of the element circuit.

Still another object of the present invention is to provide an automatic device circuit of a TV which can automatically remove a device part after a predetermined device time without the need for a separate device control microcomputer.

1 is a circuit diagram of a conventional television element.

2 is a television automatic device circuit diagram according to an embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

1, 11 element part 2: rectification and smoothing circuit

3, 14: relay driver 4, 15: power supply circuit

5: microcomputer 6: TV circuit

7, 8, 16, 17: power line 12: rectifier circuit

13: smoothing circuit

In order to achieve the above objects, the TV automatic element circuit according to the present invention is a device coil for generating an alternating magnetic field by an input AC power supply, and for limiting the current to limit the current to the device coil connected in series An element portion configured to include a resistor, a relay portion for shorting a current applied to the element portion to cut off the current applied to the element portion, and a transistor for driving the relay by an input DC power source. And a switch circuit for cutting off the current supplied to the element portion after a predetermined element time, a current limiting resistor and a time constant circuit of the element portion, and determining the element time of the element portion by the time constant. It is provided with a rectification and smoothing circuit which converts an input AC power into a DC power and supplies it to the control terminal of the transistor. And that is characterized.

Other objects and advantages of the present invention in addition to the above object will be apparent from the description of the preferred embodiment of the present invention with reference to the accompanying drawings.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to FIG.

FIG. 2 shows a TV device circuit according to an embodiment of the present invention, wherein the device circuit of FIG. 2 includes a device portion 11 consisting of a device current limiting resistor R1 and a device coil L, and a device portion 11. ), A rectifier circuit 12 and a smoothing circuit 13 for converting an input AC power source into a DC power source and supplying the relay drive unit 14 to the relay drive unit 14 are removed.

In the TV element circuit shown in Fig. 2, the element portion 11 and the rectifying and smoothing circuits 12, 13 are connected in series to the first and second power supply lines 16, 17. The element unit 11 performs an element operation when AC power is applied from the first and second power lines 16 and 17 through the rectification and smoothing circuits 12 and 13. Here, the rectifier circuit 12 serves to supply a DC power to the smoothing circuit 13. The charging capacitor C1 of the smoothing circuit 13 is connected in series with the element current limiting resistor R1 so that the device time can be adjusted by the time constant of the capacitor C1 and the resistor R1. In addition, the rectifier and smoothing circuits 12 and 13 supply DC power to the relay driver 14. The relay driver 14 removes the element part 11 by shorting the relay switch RS after a predetermined time.

In detail, when the user turns on the power switch SW, a current path is provided when a current having a positive polarity is supplied to the first power line 16 and a current having a negative polarity is supplied to the second power line 17. Is as follows. The current supplied through the first power line 16 is supplied to the rectifier circuit, that is, the first diode D1 of the diode bridge circuit 12 via the element current limiting resistor R1 and the element coil L. The element circuit is configured by being supplied to the second power supply line 17 via the first diode D1, the charging capacitor C1, and the second diode D2. On the contrary, when a current having a negative polarity is supplied to the first power supply line 16 and a current having a positive polarity is supplied to the second power supply line 17, the current supplied through the second power supply line 17 is The first power supply line is connected via the third diode D3 of the diode bridge circuit 12, the charging capacitor C1, the fourth diode D4, the element coil L, and the element current limiting resistor R1. 16) an element circuit is constructed. As such, when a power source of the TV is applied, an element circuit is automatically configured to generate an alternating magnetic field in the element coil L, thereby forming the shadow mask. When the current is supplied through the above-described path and the voltage is charged in the charging capacitor C1, the current no longer flows toward the element portion 11. In this case, the charging time of the charging capacitor (C1) can be adjusted by the time constant, that is, the capacitance of the capacitor (C1) and the value of the element current limiting resistor (R1), so that it is possible to adjust the device time unlike in the prior art. do. In addition, when the power switch SW is turned off to the TV and the power is not applied, the element circuit described above is discharged when the TV power is applied again by discharging the current charged in the charging capacitor C1 by the discharge resistor R2. It works as one. Here, the discharge resistance (R2) value is designed to be large enough to have no problem in the operation of the device.

On the other hand, while the above-described element circuit unit 11 operates and the voltage charged in the charging capacitor C1 increases, the resistor R3 connected in series between the first node N1 and the second node N2. In the time constant circuit consisting of and capacitor C2, when the voltage charged to capacitor C2 becomes greater than the sum of the voltage applied to the base and emitter of transistor Q and the voltage applied to emitter resistor R4. When (Q) is turned on, the relay RE operates. Here, the zener diode ZD connected in series between the resistor R3 and the capacitor C2 serves to lower the voltage, and the fifth diode D5 connected in parallel to the relay RE is connected to the relay RE. It is to prevent the back electromotive force is taken. In this way, when the relay RE operates, the relay switch RS of the element circuit unit 1 is turned on and shorted, so that the element circuit unit 11 does not operate. In this case, the time constant value of the time constant circuit composed of the resistor R3, the zener diode ZD, and the capacitor C2 is obtained by obtaining the device circuit portion 11 and the bridge in order to obtain a sufficient device effect, that is, to increase the device time. It is set larger than the time constant value formed by the circuit 12 and the charging capacitor C1.

As a result, the TV element circuit according to the present invention automatically operates when the power is applied, and causes the shadow mask to be decomposed. The device time is arbitrarily adjusted by the time constants of the device current limiting resistor R1 and the charging capacitor C1. It becomes possible. In addition, the surge current can be limited by the element current limiting resistor R1. In addition, after a predetermined device time, the operation time of the relay is arbitrarily adjusted by the time constant of the relay driver, thereby preventing deterioration in image quality due to leakage current flowing through the device unit 11.

As described above, according to the TV automatic element circuit according to the present invention, there is no heating component such as a conventional PTC thermistor, thereby ensuring the safety of the TV set. Further, according to the TV automatic element circuit according to the present invention, the element time can be arbitrarily adjusted by the time constant of the rectification and smoothing circuits connected in series with the element section. In addition, according to the TV automatic device circuit according to the present invention by the time constant circuit of the relay driver for removing the device circuit it is possible to arbitrarily adjust the relay drive time without the need for a separate microcomputer control as in the prior art. Furthermore, according to the TV automatic device circuit according to the present invention, by using the rectification and smoothing circuit included in the power supply circuit as part of the device circuit, it is possible to design both circuits as a block on the printed circuit board as well as to reduce the cost. do.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (5)

In the automatic element circuit of a television, An element part for performing an element, comprising an element coil for generating an alternating magnetic field by an input AC power source, a current limiting resistor for limiting current in the element coil connected in series with the element coil; It is composed of a relay for shorting the current applied to the element portion when a current is input, and a transistor for driving the relay by an input DC power supply to block the current supplied to the element portion after a predetermined element time. A switch circuit for The device unit and the current limiting resistor and the time constant circuit are configured and the device time is determined by the time constant, and the rectification is performed by converting the input AC power into DC power and supplying it to the control terminal of the transistor. And a smoothing circuit. delete The method of claim 1, The switch circuit And a second time constant circuit connected to the control terminal of the transistor to determine the driving time of the transistor together with the time constant circuit to determine the device time of the element section. The method of claim 1, Wherein said rectifying and smoothing circuit is included in a power supply circuit of said television set. delete