KR200327956Y1 - CRT display apparatus - Google Patents

Abstract

The present invention relates to a CRT display device. The present invention is a CRT display device having a high-voltage transformer and a control grid, comprising a current controller for outputting a current by an input signal, and a zener diode for receiving the current output from the current controller, the input terminal of the control grid Is a CRT display device connected to the zener diode to maintain a constant voltage of the control grid. As a result, it is possible to maintain a constant control grid voltage against beam current fluctuations and to prevent luminance fluctuations.

Description

Crt display apparatus {CRT display apparatus}

The present invention relates to a CRT display device.

The voltage output from the fly back transformer (FBT) of the CRT display device is about 26 kV. This high voltage is supplied to the cathode electrode of the CRT, and a control grid requiring a relatively high voltage is supplied with a voltage of several hundred volts derived from the secondary induction coil of the high-voltage transformer.

1 is a circuit diagram of supplying a voltage of a control grid in a conventional CRT display apparatus.

As shown in FIG. 1, the CRT display apparatus includes a high voltage transformer 100, a negative power supply unit 110, a positive power supply unit 120, and a return control unit 130.

The high pressure transformer 110 (FBT) has a primary induction coil 101 and a secondary induction coil 102. The secondary induction coil 102 has a relatively large turns ratio compared to the primary induction coil 101 and amplifies the voltage applied to the primary induction coil 101 and supplies it to the cathode of the CRT.

The negative power supply unit 110 includes a third induction coil 111, a diode D3, a capacitor C2, and resistors R3 and R2.

The third induction coil 111 is coupled to the second induction coil 102 of the high-pressure transformer 100 to induce a negative voltage. Since the third induction coil 111 has a relatively small winding with respect to the second induction coil 102, the voltage of the second induction coil 102 up to 26 kV is reduced to about -140 to -200 V. Guided to the third induction coil (111).

The diode D3 and the capacitor C2 smooth the negative AC voltage induced by the third induction coil 111 to a DC voltage. The resistor R3 discharges the high voltage charged in the capacitor C2 when the power is cut off.

The positive power supply unit 120 includes a zener diode ZD1, a pnp type BJT Q1, a diode D1, and a resistor R4.

Zener diode (ZD1) receives the Vcc voltage and supplies a voltage suitable for the design condition to the emitter terminal of the BJT (Q1).

The base of the pnp type BJT Q1 receives a predetermined control signal from the Video Mute terminal. When a voltage is applied to the base terminal so that there is a forward bias between the base and emitter terminals, a current is output to the collector terminal, and a predetermined voltage drop occurs in the resistor R4 by the collector current, so that a positive voltage corresponding to the design condition is applied to the node A. Occurs in

The retrace control unit 130 has a capacitor C1 and a diode D2.

The capacitor C1 is connected to the V-FLB terminal to block the DC voltage from the control signal coming from the V-FLB, and supply the pulse voltage of AC to the node A through the diode D2.

The voltage generated at the node A is supplied to the control grid terminal G1 through the resistor R1, and under normal conditions, the applied voltage of the control grid terminal G1 reaches about -69V. The control grid voltage V _G1 is obtained by the sum of the outputs of the negative power supply unit 110, the positive power supply unit 120, and the retrace control unit 130.

The control signal input through the video mute terminal conducts the BJT (Q1) by maintaining a low level voltage under normal operating conditions. However, when the system is stabilized during power-on or during the conversion of a frequency change signal from the processor to another frequency band, the screen may be incomplete. During this period, the BJT (Q1) is cut off by applying a high voltage to the Video Mute terminal. The Vcc voltage is not transmitted to the node A by turning off the transistor Q1, and the high reverse voltage of the negative power supply unit 110 is applied to the control grid as it is. The high reverse voltage prevents the electron beam emitted from the electron gun from reaching the fluorescent plate and prevents the irregular video on the screen from appearing and prevents the fluorescent plate from burning due to a spot phenomenon even when the power is turned off. do.

A voltage signal having the same period as the vertical period of the scanning line is applied to the V-FLB terminal so that the vertical retrace of the electron beam is not visible on the screen. That is, the input control signal of the V-FLB has a high level of positive voltage under normal operating conditions and a low level signal voltage during the return time of the electron beam so that a high reverse voltage (negative voltage) is applied to the control grid. do. The electron beam cannot reach the fluorescent plate during the vertical retrace time so that the retrace of the electron beam is not visible on the screen.

In the conventional power supply circuit of the control grid, if the beam current of the CRT changes due to a change in load (a change in luminance, etc.), a voltage change appears in the secondary induction coil 102 of the high-voltage transformer 100 and such a voltage change There was a problem of changing the brightness of the screen by affecting the control grid voltage (V _G1 ).

That is, when the current of the beam is large, the voltage V _G1 of the control grid approaches the positive voltage, and when the current of the beam is small, the negative value becomes larger.

Table 1 shows the variation of the control grid voltage (V _G1 ) and the induced voltage variation of the third induction coil (-Vd) according to the frequency of the scan line, the minimum and maximum of the beam current when the resistance is 82k ?? .

<Table 1>

Mode (H / V) Resistance R4 = 82k ?? For minimum beam current For maximum beam current V _G1 -Vd V _G1 -Vd 31 kHz / 60 Hz -64.80 -187.3 -67.10 -193.3 37 kHz / 85 Hz -63.90 -184.1 -67.50 -193.3 43kHz / 85Hz -65.10 -187.8 -68.80 -197.6 46 kHz / 75 Hz -60.20 -173.8 -67.40 -193.5 48 kHz / 60 Hz -61.90 -179.2 -67.40 -195.0 53kHz / 85Hz -66.70 -192.3 -68.40 -197.1 56 kHz / 75 Hz -63.40 -182.8 -69.40 -199.6 60 kHz / 75 Hz -61.40 -177.6 -69.90 -202.6 68 kHz / 85 Hz -66.20 -190.7 -70.20 -201.6 79 kHz / 75 Hz -60.30 -174.3 -71.50 -204.7 91 kHz / 85 Hz -64.40 -185.6 -69.40 -199.3 93 kHz / 75 Hz -65.90 -190.0 -70.30 -202.1

It is an object of the present invention to provide a high quality CRT display apparatus in which the control grid voltage is kept constant with respect to the beam current variation of the CRT.

1 is a circuit diagram for supplying a voltage of a control grid in a conventional CRT display device;

2 is a circuit diagram of supplying a voltage of a control grid in a CRT display device according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10, 100: high pressure transformer 11, 101: primary induction coil

12, 102: secondary induction coil 20, 110: negative power supply

21, 111: third induction coil 30, 120: positive power supply

40, 130: retrace control unit

In the CRT display device having a high-voltage transformer and a control grid according to the present invention, the object includes a current controller for outputting a current by an input signal, and a zener diode for receiving the current output from the current controller, The input terminal of the control grid may be achieved by a CRT display device connected to the zener diode to maintain a constant voltage of the control grid.

Here, the input terminal of the control grid is preferably applied to the induced voltage induced in the third induction coil coupled to the second induction coil of the high-voltage transformer. The current controller may have a BJT and a collector terminal of the BJT may be connected to the zener diode.

2 is a circuit diagram of supplying a voltage of a control grid in a CRT display device according to an embodiment of the present invention.

As shown in FIG. 2, the CRT display apparatus includes a high voltage transformer 10, a negative power supply unit 20, a positive power supply unit 30, and a retrace control unit 40.

The high pressure transformer 10 (FBT) has a primary induction coil 11 and a secondary induction coil 12. The secondary induction coil 12 has a relatively large turns ratio compared to the primary induction coil 11 and amplifies the voltage applied to the primary induction coil 11 and supplies it to the cathode of the CRT.

The negative power supply unit 20 includes a third induction coil 21, a diode D3, a capacitor C2, and resistors R2 and R3.

The third induction coil 21 is coupled to the second induction coil 12 of the high-pressure transformer 10 to induce a negative voltage. Since the third induction coil 21 has a relatively small winding with respect to the second induction coil 12, the voltage of the second induction coil 12 up to 26 kV is reduced to about -140 to -200 V. The third guide coil 21 is guided.

The diode D3 and the capacitor C2 smooth the negative AC voltage induced by the third induction coil 21 to the DC voltage (-Vd). The resistor R3 discharges the high voltage (-Vd) charged in the capacitor C2 when the power is cut off.

The positive power supply unit 30 has zener diodes ZD1, ZD2, ZD3, a pnp type BJT Q1, and a diode D1.

Zener diode (ZD1) receives the Vcc voltage and supplies a voltage suitable for the design condition to the emitter terminal of the BJT (Q1).

The base of the pnp type BJT Q1 receives a predetermined control signal from the Video Mute terminal. When voltage is applied to the base terminal so that there is a forward bias between the base and emitter terminals, current is output to the collector terminal.

In Zener diodes ZD2 and ZD3, a constant voltage drop determined by the current flowing in the reverse direction occurs, so that a positive voltage corresponding to the design condition is generated at the node A.

BJT (Q1) of the pnp type is a transistor used as an example of the current controller. The base of the transistor Q1 receives a predetermined control signal from the Video Mute terminal. In addition to the pnp type BJT of the present embodiment, the current controller may use various transistor elements, and may be implemented to meet the object of the present invention by using a combination of ASIC and elements.

The retrace control unit 40 has a capacitor C1 and a diode D2.

The capacitor C1 is connected to the V-FLB terminal to block the DC voltage from the control signal coming from the V-FLB, and supply the pulse voltage of AC to the node A through the diode D1.

The voltage generated at the node A is supplied to the control grid terminal G1 through the resistor R1, and under normal conditions, the applied voltage of the control grid terminal G1 reaches about -69V. The control grid voltage V _G1 is obtained by the sum of the outputs of the negative power supply unit 110, the positive power supply unit 120, and the retrace control unit 130.

The purpose and function of the control signal input through the Video Mute terminal and the V-FLB terminal are the same as above.

When the beam current of the CRT changes according to the load change of the CRT, the reverse voltage (-Vd) output from the negative power supply unit 20 changes. This voltage change changes the current output from the current controller. That is, the current output from the collector of the transistor Q1 becomes ?? times the current input to the base terminal. However, the collector current varies in magnitude depending on the voltage difference Vec between the emitter terminal and the collector terminal. The current fluctuation causes a voltage change across the zener diodes ZD2 and ZD3 falling from the zener diodes ZD2 and ZD3 and keeps the voltage at the node A constant.

Even if the negative voltage output from the negative power supply unit 20 fluctuates, a constant voltage V _G1 is input to the control grid due to the variation of the output current of the current controller and the voltage of the zener diodes ZD2 and ZD3. .

Table 2 shows the variation of the control grid voltage V _G1 according to the frequency of the scan line, the minimum and maximum beam current, and the third induction coil 21 when the control diodes ZD2 and ZD3 are used according to the present invention. The variation of induced voltage (-Vd) is shown.

<Table 2>

Mode (H / V) When using Zener diode (breakdown voltage 36V) For minimum beam current For maximum beam current V _G1 -Vd V _G1 -Vd 31 kHz / 60 Hz -69.10 -187.3 -69.10 -193.3 37 kHz / 85 Hz -69.30 -184.1 -69.30 -193.3 43kHz / 85Hz -69.20 -187.8 -69.20 -197.6 46 kHz / 75 Hz -69.10 -173.8 -69.10 -193.5 48 kHz / 60 Hz -69.00 -179.2 -69.00 -195.0 53kHz / 85Hz -69.20 -192.3 -69.20 -197.1 56 kHz / 75 Hz -69.10 -182.8 -69.10 -199.6 60 kHz / 75 Hz -69.10 -177.6 -69.10 -202.6 68 kHz / 85 Hz -69.10 -190.7 -69.10 -201.6 79 kHz / 75 Hz -69.10 -174.3 -69.20 -204.7 91 kHz / 85 Hz -69.20 -185.6 -69.20 -199.3 93 kHz / 75 Hz -69.10 -190.0 -69.10 -202.1

According to the present invention, luminance fluctuation can be prevented by maintaining a constant control grid voltage against beam current fluctuation.

Claims (3)

In the CRT display device having a high-voltage transformer and a control grid, A current controller for outputting current by an input signal, A zener diode receiving a current output from the current controller, And an input terminal of the control grid is connected to the zener diode to maintain a constant voltage of the control grid. The method of claim 1, The input terminal of the control grid CRT display apparatus characterized in that the induced voltage is applied to the third induction coil coupled to the second induction coil of the high-voltage transformer The method according to claim 1 or 2, And the current controller has a BJT and a collector terminal of the BJT is connected to the zener diode.