KR20000021534A - Degaussing circuit of image receiving tube - Google Patents

Abstract

PURPOSE: A degaussing circuit of an image receiving tube is provided to maintain a constant current to a degaussing coil independently of a current voltage size by using an insulated gate bipolar transistor. CONSTITUTION: A degaussing circuit of an image receiving tube comprises a degaussing coil(Lp), a micro computer(10), a switching driving device(20), and an insulated gate bipolar transistor(30). The degaussing coil is installed around an image receiving tube. The micro computer generates a degaussing control signal to remove a magnetization of the image receiving tube. The switching driving device outputs a driving signal when the degaussing control signal is input. The insulated gate bipolar transistor provides the alternative current through a posistor to a degaussing coil(Lp).

Description

A degaussing circuit in a CRT

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a degaussing circuit of a receiver, and in particular, a degassing circuit of a receiver configured to supply a constant current to a degaussing coil at all times regardless of the magnitude of a commercial AC voltage using a gate insulated bipolar transistor (IGBT). It relates to a Gaussing circuit.

In general, when the shadow mask or the attachment tool of the water pipe is magnetized due to the influence of geomagnetism or external magnetism, staining may occur on the screen. As described above, when any part of the water pipe is magnetized, color purity may appear. Falls out.

In addition, even if the color purity is well adjusted in the magnetized state, if the direction of the water pipe is changed, the color purity deteriorates due to the influence of residual magnetism. Therefore, the magnetized part of the shadow mask must be demagnetized.

At this time, removing the magnetism in the magnetized part is called degaussing (消磁).

In general, a degaussing element is used to demagnetize a water pipe. The degaussing coil is a coil group installed around the water pipe, and a degaussing coil is connected to a power circuit and a power switch or degaussing switch is used. Each time the same switching means is turned on / off, an alternating current flows through the degaussing coil so as to apply an alternating magnetic field on the shadow mask, thereby automatically demagnetizing the element.

FIG. 1 is a circuit diagram illustrating an example of a general degaussing circuit using a positive temperature characteristic thermistor (Posistor). Referring to FIG. 1, the operation of a general degaussing circuit will be described below.

When the user turns on the power switch or the degaussing switch, the microcomputer 1 detects this and outputs a high level degaussing control signal.

The high level degaussing control signal is applied to the base terminal of the NPN transistor Q1 through a resistor R1 to turn on the transistor Q1.

Since the transistor Q1 is turned on, one side of the relay RL1 coil is grounded. Therefore, a predetermined voltage 12V connected to the other side of the relay RL1 coil is applied to the relay RL1 coil. A magnetic field is formed, and the relay RL1 switch is turned on by the magnetic field.

As the relay RL1 is switched on, a commercial AC current flows through a desistoring coil (Posistor). L _D ), And an element is applied by applying an alternating magnetic field on the shadow mask.

In this case, the resistor is a thermosensitive resistor. Since the resistor has a characteristic that the resistance value gradually increases as the temperature increases, the resistor P1 initially has a small resistance value when the power switch SW is turned on. Degaussing coil L _D ), But a lot of current flows, but as time elapses, the temperature increases due to the current, and thus the resistance value of the transistor becomes larger. L _D The current flowing in the 감소 gradually decreases and eventually becomes zero.

Therefore, the degaussing coil ( L _D ), The attenuation current (degaussing current) is supplied for a certain time (typically 1 second), and the device is automatically formed.

However, as described above, the degaussing circuit of the conventional water tube uses a commercial AC current degaussing coil ( L _D ) By applying an alternating magnetic field on the shadow mask, and degassing coil ( L _D Power consumption increases because the amount of current flowing in the filter becomes larger than necessary, and conversely, when the commercial AC voltage is smaller than the rated voltage, the degaussing coil ( L _D Since the amount of the current flowing in the i) becomes less than necessary, there is a problem that the element on the shadow mask is not properly made.

Accordingly, the present invention was devised to solve the above problems, and the circuit of the present invention always supplies a constant current to the degaussing coil using a gate insulated bipolar transistor (IGBT) regardless of the magnitude of a commercial AC voltage. Its purpose is to provide a degaussing circuit for the receiving tube.

Degaussing circuit of the water pipe according to the present invention for achieving the above object,

Degaussing coils installed around the water pipe;

A microcomputer that outputs a degaussing control signal to cancel a magnetization of a water pipe generated by a geomagnetism or an external magnetism;

A switching driver for outputting a driving signal when the degaussing control signal is input; And

And a gate insulated bipolar transistor that is switched on when the driving signal is input and supplies a commercial AC current to the degaussing coil through a transistor.

1 is a circuit diagram showing a degaussing circuit of a general water pipe;

2 is a circuit diagram showing a degaussing circuit of a water pipe according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: micom 20: switching drive unit

30: gate insulated bipolar transistor L _D Degaussing Coil

Posistor: Posistor Q1: Transistor

IGBT 1,2: first and second N-channel gate insulated bipolar transistors

D 1,2: first and second diode C1: capacitor

R 1,2,3: resistance

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

2 is a circuit diagram showing a degaussing circuit of a water pipe according to the present invention.

As shown in FIG. 2, the circuit of the present invention includes a degaussing coil installed around a water pipe ( L _D ) And; A microcomputer 10 for outputting a degaussing control signal to cancel the magnetization of the water pipe generated by the geomagnetism or the external magnetism; A switching driver 20 outputting a driving signal when the degaussing control signal is input; And when the driving signal is input, the switching signal is turned on to supply a commercial AC current through a desistoring coil. L _D Is constituted by a gate insulated bipolar transistor (30).

Here, the switching driver 30 has a base terminal receiving a degaussing control signal from the microcomputer 10, a collector terminal receiving a predetermined voltage Vcc, and an emitter terminal receiving resistors R2 and R3. It is connected to the gate terminal of the insulated bipolar transistor 30, and when the degaussing control signal is input, it is turned on to supply a drive signal to the gate insulated bipolar transistor 30 to switch on the gate insulated transistor 30. Is composed of a PNP transistor Q1.

In addition, the gate insulated bipolar transistor 30 is switched on when a gate terminal receives the driving signal, a drain terminal and a source terminal are connected to the commercial AC voltage supply line, and a driving signal is input, so that the commercial AC voltage is positive ( In the + component, the commercial alternating current is passed through the L _D A first N-channel gate insulated bipolar transistor (IGBT1) supplied to; The gate terminal receives the driving signal, the drain terminal and the source terminal are connected to the commercial AC voltage supply line, and are switched on when the driving signal is input. When the commercial AC voltage is a negative component, Posistor) allows the degaussing coil ( L _D Second N-channel gate insulated bipolar transistor (IGBT2) to be supplied to; A first connection connected in parallel with the first N-channel gate insulation bipolar transistor IGBT1 to provide a flow path for commercial AC current flowing through the second N-channel gate insulation bipolar transistor IGBT2. Diode D1; And a second N-channel gate insulated bipolar transistor IGBT2 connected in parallel and connected in a reverse direction to provide a flow path of commercial AC current flowing through the first N-channel gate insulated bipolar transistor IGBT1. It consists of two diodes D2.

Next, the operation of the circuit according to the present invention configured as described above will be described.

When the microcomputer 10 outputs a high level degaussing control signal to demagnetize the water tube, the high level degaussing control signal is applied to the base terminal of the transistor Q1 through the resistor R1. The transistor Q1 is turned on.

As the transistor Q1 is turned on, the predetermined voltage Vcc supplied through the transistor Q1 is divided by the resistors R2 and R3.

In this case, the driving signal, that is, the voltage divided by the resistor is supplied to the gate voltages of the first gate insulation bipolar transistor IGBT1 and the second gate insulation bipolar transistor IGBT2.

Accordingly, the first gate insulated bipolar transistor IGBT1 and the second gate insulated bipolar transistor IGBT2 are switched on, and a commercial alternating current is applied to the degaussing coil through a transistor. L _D ), And an element is applied by applying an alternating magnetic field on the shadow mask.

That is, when the commercial AC voltage is a positive component, the commercial AC current is degaussed through the first gate insulated bipolar transistor IGBT1 and the second diode D2. L _D ) And, on the contrary, when the commercial AC voltage is a negative component, the commercial AC current passes through the second gate insulating bipolar transistor IGBT2 and the first diode D1. L _D Is supplied.

The Insulated Gate Bipolar Transistor (IGBT) is a switching device that is generally insulated between a gate and a channel and has no direct electrical connection between the gate terminal and the channel, and is switched on / off by a gate voltage to provide a large current. Supply or cut off.

In addition, the gate insulated bipolar transistor (IGBT) has an overcurrent protection function. When the drain current of the gate insulated bipolar transistor (IGBT) increases and exceeds a predetermined value, the gate-insulated bipolar transistor (IGBT) increases a voltage between the drain and the source so that the drain current is constant. By suppressing below, even if the commercial AC voltage exceeds the rated voltage, the degaussing coil ( L _D ) Is always supplied with a constant degaussing current.

As described above, the present invention uses a gate insulated bipolar transistor (IGBT) to always maintain a constant current regardless of the magnitude of a commercial AC voltage. L _D ) Is effective in supplying.

Claims (3)

Degaussing coils installed around the water pipe ( L _D ) And; A microcomputer 10 for outputting a degaussing control signal to cancel the magnetization of the water pipe generated by the geomagnetism or the external magnetism; A switching driver 20 outputting a driving signal when the degaussing control signal is input; And When the driving signal is input, the switching signal is turned on to supply a commercial AC current through a degaussing coil (Posistor). L _D A degaussing circuit of a water tube, characterized in that it is composed of a gate insulated bipolar transistor (30) supplied to the circuit. The method of claim 1, wherein the switching driver 30, A base terminal receives a degaussing control signal from the microcomputer 10, a collector terminal receives a predetermined voltage Vcc, and an emitter terminal receives resistors R2 and R3 through a gate terminal of the gate insulation transistor 30. A PNP transistor Q1 connected to the gate insulating bipolar transistor 30 so as to be turned on when a degaussing control signal is input to supply a driving signal to the gate insulating bipolar transistor 30. Degaussing circuit of the water pipe, characterized in that. The method of claim 1, wherein the gate insulating bipolar transistor 30, The gate terminal receives the driving signal, the drain terminal and the source terminal are connected to the commercial AC voltage supply line, and are switched on when the driving signal is input. When the commercial AC voltage is a positive component, a commercial AC current is applied to the transistor. Posistor) allows the degaussing coil ( L _D A first N-channel gate insulated bipolar transistor (IGBT1) supplied to; The gate terminal receives the driving signal, the drain terminal and the source terminal are connected to the commercial AC voltage supply line, and are switched on when the driving signal is input. When the commercial AC voltage is a negative component, Posistor) allows the degaussing coil ( L _D Second N-channel gate insulated bipolar transistor (IGBT2) to be supplied to; A first connection connected in parallel with the first N-channel gate insulation bipolar transistor IGBT1 to provide a flow path for commercial AC current flowing through the second N-channel gate insulation bipolar transistor IGBT2. Diode D1; And A second N-channel gate insulated bipolar transistor IGBT2 connected in parallel and connected in a reverse direction to provide a flow path of commercial AC current flowing through the first N-channel gate insulated bipolar transistor IGBT1; A degaussing circuit of a water tube, characterized by comprising a diode (D2).