KR100250188B1 - Residual color beam deflection circuit of cathode-ray tube - Google Patents

Abstract

PURPOSE: A circuit for controlling a deflection of a remaining electron beam in CRT during a power off is to prevent a beam spot phenomenon by performing a defection operation with respect to R/G/B color beams remaining in the CRT. CONSTITUTION: A television comprises a horizontal deflection coil(18), a vertical deflection block(44) and a flyback transformer(20). The horizontal deflection coil which is connected to a collector of a switching transistor(12) controls a horizontal deflection of a CRT(10). The switching transistor performs a switching operation in response to a horizontal driving signal. The vertical deflection block controls a vertical deflection of the CRT. The flyback transformer which is connected to the collector of the switching transistor generates a high voltage to be applied to the CRT. A micom(30) controls the high voltage applied to the horizontal deflection coil and the CRT as well as a deflection of a color beam remaining in the CRT. A timer(32) sets up a deflection period with respect to the remaining color beam. A main signal controller(34) is activated during the deflection period and generates a horizontal/vertical synchronization signal for deflecting the remaining color beam. A deflection controller performs a horizontal deflection with respect to the color beam of the CRT under a control of the micom.

Description

RESIDUAL COLOR BEAM DEFLECTION CIRCUIT OF CATHODE-RAY TUBE}

The present invention relates to a residual light beam deflection control circuit of a CRT apparatus when the power is turned off. More specifically, the deflection current is set for a predetermined time with respect to the residual light beam emitted from the R / G / B electron gun of the CRT apparatus when the television is turned off. The present invention relates to a residual light beam deflection control circuit of a CRT apparatus when the power supply is turned off so as to prevent the light beam spot phenomenon caused by the residual light beam.

In general, a television for reproducing an image / audio signal is provided with a CRT apparatus for reproducing an image. According to the CRT apparatus, an R / G / B color beam corresponding to a color component of an image signal is emitted. A fluorescent panel coated with a fluorescent paint such that a G / B electron gun, a corresponding R / G / B fluorescent point is emitted when the R / G / B color beam is reached, and an R / G / B emitted from the R / G / B electron gun A porous shadow mask is provided to guide the B color beam to the R / G / B fluorescent point on the fluorescent panel accurately, and the neck of the CRT device of such a configuration is provided with R / G / B electron gun radiated from the R / G / B electron gun. A horizontal / vertical deflectometer is provided which deflects in the horizontal / vertical direction so that the / B color beam is uniformly distributed over the entire surface of the fluorescent panel.

1 is a diagram showing a power system for supplying power to a CRT device having such a configuration, wherein reference numeral 10 is provided with an R / G / B electron gun and a fluorescent panel that emit an R / G / B color beam corresponding to an image signal. A CRT device is shown, and 12 denotes a horizontal output transistor for switching in response to a horizontal duty signal Hds having a constant duty ratio applied from a horizontal drive means (not shown), and 14 and 16 denote the horizontal output transistor 12. ) Shows diodes and capacitors provided for damping the collector current appearing on the collector side.

18 denotes a horizontal deflection coil which is connected to the collector side of the horizontal output transistor 12 and acts so that the R / G / B color beam of the CRT apparatus 10 is horizontally deflected by the collector current. One end of the primary side coil is connected to the collector side of the horizontal output transistor 12 while a power source B + is applied to the primary side coil so that the secondary side coil is Represents a flyback transformer for generating a high voltage (H · V) applied to the anode electrode of the CRT device 10, 22 is a high voltage for rectifying the high voltage (H · V) applied to the anode electrode of the CRT device 10 Represents a diode. 24 is appropriately leveled with respect to the high voltage (H · V) obtained at the secondary side of the flyback transformer 20 to generate a focus voltage FOCUS to be applied to the focus electrode of the CRT apparatus 10, thereby generating the CRT. A variable resistor that provides for focusing the R / G / B color beam of the device 10, and 26 is appropriately leveled for the high voltage (H · V) to be applied to the screen electrode of the CRT device 10. A variable resistor is generated to generate a screen voltage SCREEN to accelerate the R / G / B color beam of the CRT apparatus 10.

28 is connected to the image output power source DC obtained by the intermittent current flow of the primary coil with respect to the power source B + applied to the flyback transformer 10 to convert the image signal Vin to R / G / Converted into a B signal and provided to an R / G / B electron gun of the CRT apparatus 10 to radiate an R / G / B color beam, and C denotes an image applied to the image processor 28. A smoothing capacitor for smoothing the output power is shown.

According to the above configuration, when a horizontal driving signal having a constant duty ratio is applied to the base of the horizontal output transistor 12 in the horizontal driving means during operation of the corresponding television, the horizontal output transistor 12 transmits the horizontal driving signal Hds. In response to switching), a collector current corresponding to the horizontal driving signal flows to the collector side of the horizontal output transistor 12. In response to the switching action of the horizontal output transistor 12, the primary coil of the flyback transformer 20 flows intermittently from the power source B + to obtain an image output power to be applied to the image processor 28. The image output power is applied to the image processor 28 in a state of being smoothed by the charging / discharging action of the smoothing capacitor C. FIG. Accordingly, the image processor 28 reproduces the image signal Vin by the image output power to the R / G / B signal and applies the R / G / B electron gun to the CRT apparatus 10. Accordingly, in the R / G / B electron gun of the CRT apparatus 10, an R / G / B color beam corresponding to the R / G / B color signal applied by the image processor 28 is radiated.

In addition, on the secondary side of the flyback transformer 20 in which current flows intermittently to the primary coil, a high voltage (H · V) is induced and rectified by the high voltage diode 22 according to the winding ratio, and then the CRT. A screen voltage (SCREEN) applied to the anode electrode of the device 10 and applied to the screen electrode and the focus electrode of the CRT device 10 from the high voltage (H · V) by the variable resistors 24 and 26; The focus voltage FOCUS is obtained.

Accordingly, the R / G / B color beams emitted from the R / G / B electron gun of the CRT apparatus 10 are accelerated by the screen electrode and the focus electrode to which the screen voltage SCREEN and the focus voltage FOCUS are applied. The color image is reproduced by focusing and reaching the R / G / B fluorescent point on the fluorescent panel based on the high voltage (H · V) applied through the shadow mask and applied to the anode electrode.

However, when the power of the television is turned off, the power supply B + applied to the flyback transformer 20 is cut off, and the flyback transformer 20 generates an image output power supply DC and a high voltage HV. Although not, the power supplied to the smoothing capacitor C for smoothing the image output power DC applied to the image processor 28 is applied to the image processor 28 and the CRT apparatus 10. Residual components of the high pressure (H · V) are present in the anode electrode, and the state in which the R / G / B electron gun of the CRT apparatus 10 is heated by the heater is maintained for a predetermined time. Therefore, in the R / G / B electron gun of the CRT apparatus 10, a residual R / G / B color beam is generated for a predetermined time from the power-off point and radiated toward the R / G / B fluorescent point of the fluorescent panel. Since the horizontal / vertical deflection current with respect to the CRT apparatus 10 is blocked, the deflection with respect to the residual R / G / B color beams is not performed, resulting in a beam spot phenomenon on the screen of the CRT apparatus.

Such a beam spot phenomenon on a CRT device causes a disadvantage of darkening the R / G / B fluorescent spots on a specific portion on the fluorescent panel, thereby reducing the life of the CRT device.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and when only the horizontal / vertical deflection current is applied over a predetermined time while the television is powered off, the residual R / G / B color beam is deflected so that the optical beam is deflected. It is an object of the present invention to provide a residual light beam deflection control circuit of a CRT apparatus when the power is turned off so as to prevent the beam spot phenomenon.

In order to achieve the above object, according to a preferred embodiment of the present invention, a horizontal deflection coil connected to a collector side of a horizontal output transistor that switches in response to a horizontal drive signal and performs a horizontal deflection of the CRT device and a CRT device thereof. In a television having a vertical deflection block for vertical deflection and a flyback transformer which is commonly connected to the collector side of the horizontal output transistor and generates a high voltage applied to the CRT device, the power is turned on / off by an external power control signal. A microcomputer for controlling the application of the high pressure to the horizontal deflection coil and the CRT device in response to the OFF and the deflection of the residual color beams of the CRT device; A timer for setting a deflection period for the remaining color beam of the CRT device by the microcomputer; A main signal processor which is activated during a deflection period with respect to the residual color beam under the control of the microcomputer to generate a horizontal / vertical synchronization signal for deflection of the residual color beam; There is provided a residual light beam deflection control circuit of a CRT apparatus at power off, comprising deflection control means for executing horizontal deflection of the CRT apparatus under the control of the microcomputer.

According to the present invention, the first switch unit is interposed between the horizontal output transistor and one end of the primary coil of the flyback transformer, and the second switch is interposed between the horizontal output transistor and the horizontal deflection coil. An additional device is provided for high-voltage application control of the CRT apparatus by the microcomputer.

In addition, the deflection control means includes a first switching transistor for switching in response to a horizontal synchronizing signal from the main signal processing unit activated and controlled by the microcomputer when the power control signal indicates the power OFF, and the first switching transistor. A second switching transistor connected to a collector of a transistor and inducing a power supply corresponding to the horizontal synchronous signal on a secondary side thereof, a second switching transistor having a base connected to a secondary power supply of the horizontal transformation transformer, and switching; A decompression transformer for connecting a third switch portion for setting a horizontal deflection path of the collector current appearing in the collector of the transistor, and one end of the primary side in common to the collector side of the second switching transistor, so as to obtain a decompressed power on the secondary side. Will be made.

According to the residual light beam deflection control circuit of the CRT apparatus when the power is turned off according to the present invention, the high voltage applied to the anode electrode of the CRT apparatus is turned off for a predetermined time in the horizontal and vertical deflection coils when the television is turned off. By allowing the deflection current to be applied, deflection of the R / G / B color beam remaining in the CRT device is made, thereby preventing the beam spot phenomenon.

1 is a block diagram illustrating a power supply system for a CRT apparatus employed in a general television;

2 is a view showing the configuration of the residual light beam deflection control circuit of the CRT apparatus at power off according to the present invention.

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

10: CRT device, 12: horizontal output transistor,

20: flyback transformer, 30: microcomputer,

32: timer, 34: main signal processing section,

36: horizontal drive transistor, 38, 48: horizontal transformer,

40, 42: first and second switch portions, 46, 50: first and second switching transistors,

54: third switch section.

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

FIG. 2 is a view showing a residual light beam deflection control circuit of a CRT apparatus when a power is turned off according to a preferred embodiment of the present invention. FIG. 10 is a graph illustrating an R / G / B electron gun and an R / G / B fluorescent point for reproducing an image. 1 is a CRT device described with reference to FIG. 1 having a fluorescent panel, 12 is a horizontal output transistor switching by a horizontal drive signal Hds, 18 is a horizontal deflection coil for horizontal deflection of the CRT device 10, 20 shows a high voltage H · V applied to the CRT device 10, a screen voltage SCREEN, a focus voltage FOCUS, and an image output power DC applied to the image processor 28. It is the flyback transformer described.

In FIG. 2, reference numeral 30 denotes a microcomputer for controlling the operation of a corresponding television in response to, for example, a power control signal Pc for power on / off applied from a remote controller, and the microcomputer 30 controls power supply. When the signal Pc indicates the power off, the control is performed such that horizontal / vertical deflection is performed with respect to the CRT apparatus 10 for a predetermined time. 32 denotes a timer for setting horizontal / vertical deflection timing for a predetermined time by the microcomputer 30 when the power is turned off, and 34 denotes an image IF (Intermediate frequency) processing module ( (Not shown) includes a function of the image processing unit 28 of FIG. 1 for reproducing the video IF signal PIF when applied to the IF conversion process and is perpendicular to the horizontal synchronous signal Hsync from the video IF signal PIF. A main signal processing unit which provides a synchronization signal Vsync.

36 denotes a horizontal drive transistor that switches by the horizontal synchronizing signal Vsyn applied from the main signal processor 34 to support the generation of the horizontal drive signal, and 38 denotes a power supply B + at one end thereof and the other end thereof. The horizontal drive signal Hds is obtained on the secondary side according to the switching action connected to the collector side of the horizontal drive transistor 36 and matched to the horizontal synchronous signal Hsync of the horizontal drive transistor 36. The horizontal transformer transformer applied to the base of the output transistor 12 is shown. 40 denotes a first switch part interposed between the collector of the horizontal output transistor 12 and one end of the flyback transformer 20 to switch by the switching control signal SW1 of the microcomputer 30. The first switch 40 maintains the connection state by the switching control signal SW1 of the microcomputer 30 when the power control signal Pc applied to the microcomputer 30 is kept in the power ON state. On the other hand, when the power control signal Pc is inverted to the power OFF state, the current path for the primary coil of the flyback transformer 20 is switched ON / OFF by maintaining the non-connected state under the control of the microcomputer 30. Done.

In FIG. 2, reference numeral 42 denotes that the microcomputer 30 is controlled to be interlocked with the first switch unit 40 in accordance with the power ON / OFF state indicated by the power control signal Pc. A second switch section for interrupting the current path to the deflection coil 18, 44 indicates a vertical deflection signal based on the vertical synchronization signal (Vsync) applied from the main signal processing section 34 to generate a vertical deflection coil 44a. Denotes a vertical deflection block for performing vertical deflection with respect to the CRT apparatus 10.

46 is a first switching transistor constituting deflection control means for deflecting the remaining light beams of the CRT apparatus when the power is executed under the control of the microcomputer 30, wherein the first switching transistor 46 is the base thereof. The horizontal synchronizing signal Hsync is connected to the horizontal synchronizing signal Hsync. 48, power supply B + is applied to one end of the primary side coil and the collector side of the first switching transistor 46 is connected to the other end of the primary side coil so that the bias control means according to the present invention is horizontal in the secondary side coil. A second horizontal transformer transformer in which a horizontal deflection current corresponding to a synchronous signal is induced, and 50 denotes a base connected to one end of a secondary coil of the second horizontal transformer transformer 48 while forming a deflection control means according to the present invention. And switching switching corresponding to the horizontal deflection current induced in the secondary coil.

52, one end of the primary coil is connected to the collector side of the second switching transistor 50 while constituting the deflection control means, and according to the switching action of the second switching transistor 50, Depressurizing transformer that generates L · V so that it can be used as a standby power supply when the power is turned off. Preferably, according to the depressurizing transformer 52, the low voltage (L · V) obtained from the secondary coil is The primary coil has a winding ratio equal to the number of turns of the primary coil of the flyback transformer 20 so that the primary coil is transformed at an appropriate ratio with respect to the high voltage (H · V) obtained from the secondary coil of the flyback transformer 20. Will have 54, one end of which is commonly connected to the collector side of the second switching transistor 50 while the other end thereof is connected to one end of the horizontal deflection coil 18 while constituting the deflection control means according to the present invention. Is a third switch which is switched switching control with the first and second switch units 40 and 42 in reverse, and the third switch unit 54 maintains the power control signal Pc in the power ON state. If the power control signal Pc is inverted to the power OFF state, the microcomputer 30 is maintained in a non-connected state. During this, the path for applying the deflection current is set.

Next, the operation of the residual light beam deflection control circuit of the CRT apparatus during power off according to the present invention having the above-described configuration will be described in detail.

First, when the power control signal Pc is maintained in the power ON state with respect to the microcomputer 30, the microcomputer 30 switches the switching control signal so that the first and second switch units 40 and 42 are connected. While applying the SW1 and SW2, the third switch unit 54 applies the switching control signal SW3 to be in a non-connected state and activates the main signal processing unit 34. Then, the main signal processor 34 reproduces and processes the image IF signal PIF of a specific channel applied from the image IF processing module, so that the R / G / B color signal is similar to the image processor 28 shown in FIG. Is applied to the R / G / B electron gun of the CRT apparatus 10 correspondingly.

In addition, the horizontal synchronizing signal Hsync obtained by the main signal processing unit 34 is applied to the base of the horizontal driving transistor 36 so that the horizontal driving transistor 36 is consistent with the horizontal synchronizing signal Hsync. In this case, the current by the power source B + flows intermittently through the primary coil of the first horizontal transformer transformer 38 so that the secondary coil has a horizontal drive signal with the same period as the horizontal synchronization signal. (Hds) is displayed.

The horizontal drive signal Hds is applied to the base of the horizontal output transistor 12 to cause the horizontal output transistor 12 to switch and appear on the collector side by the switching action of the horizontal output transistor 12. The collector current causes the current to flow intermittently through the primary coil of the flyback transformer 20. As a result, a high voltage (H · V) is obtained from the secondary coil of the flyback transformer 20 so that the CRT apparatus ( 10 is applied to the anode electrode, and the focus voltage FOCUS of the CRT apparatus 10 is changed by an appropriate level change of the high voltage (H · V) (that is, the resistance value of the variable resistors 24 and 26 shown in FIG. 1). ) And the screen voltage SCREEN are obtained.

In addition, the vertical synchronization signal Vsync provided from the main signal processor 34 is applied to the vertical deflection block 44, and the vertical deflection coil (Vsync) is generated by the horizontal deflection signal generated by the vertical deflection block 44. 44a) acts to cause vertical deflection of the CRT apparatus 10. FIG.

Accordingly, the horizontal deflection of the R / G / B color beam emitted from the R / G / B electron gun of the CRT apparatus 10 in response to the R / G / B color signal reproduced by the main signal processor 34 is performed. On the R / G / B fluorescent point on the fluorescent panel based on the high pressure (H · V) applied to the anode electrode in the horizontal and vertical deflection by the coil 18 and the vertical deflection coil 44a. By reaching this, color images can be reproduced.

In such a state, when the power control signal Pc applied to the microcomputer 30 indicates power off, the microcomputer 30 is configured to switch the first and second switching units by the switching control signals SW1 and SW2. The third switching unit 54 is controlled to be connected by the switching control signal SW3, and the main signal processing unit 34 is activated for a predetermined time. The state is controlled to be maintained.

For example, the microcomputer 30 controls the main signal processor 34 for a predetermined time set in the timer 32 for a time sufficient to remove the high voltage component remaining on the anode electrode of the CRT apparatus 10 from the time when the power is turned off. In addition, the main signal processor 34 applies the vertical synchronizing signal and the horizontal synchronizing signal to the CRT apparatus 10 so as to perform a deflection operation on the R / G / B color beam.

Therefore, as the first switching part 40 interposed between the collector side of the horizontal output transistor 12 and one end of the primary side coil of the flyback transformer 20 remains unconnected, the flyback thereof On the secondary side of the transformer 20, the high pressure (H · V) is not induced. In addition, as the second switching unit 42 is maintained in a non-connected state, a path through which the collector current of the horizontal output transistor 12 is applied to the horizontal deflection coil 18 is blocked.

In this state, the horizontal synchronization signal Hsync generated when the main signal processing unit 34 is activated for a predetermined time is applied to the base side of the first switching transistor 46, and accordingly, the first switching transistor. 46 is matched to the horizontal synchronization signal (Hsync) to switch. The secondary coil of the second horizontal transformer transformer 48 having one end of the primary coil connected to the collector side by the switching action of the first switching transistor 46 is connected to the switching action of the first switching transistor 46. In response, the power having the same period as that of the horizontal synchronization signal Hsync is induced and applied to the base of the second switching transistor 50. Accordingly, the second switching transistor 50 switches at substantially the same period as the horizontal synchronous signal Hsync, and accordingly, a collector current appears on the collector side of the second switching transistor 50 to the microcomputer 30. It is applied to the horizontal deflection coil 18 through the third switch portion 54 which is connected when the power is off. Further, the collector current appearing on the collector side of the second switching transistor 50 is also applied to the primary side coil of the decompression transformer 52 having the same turns ratio as the primary side coil of the flyback transformer 20 and the secondary side thereof. The coil is induced with a low level of low voltage (H · V (for example, use as a standby power supply)) compared with the high voltage (H · V) induced by the secondary coil of the flyback transformer 20.

Therefore, the horizontal deflection coil 18 is horizontal to the CRT apparatus 10 due to the horizontal deflection signal applied through the third switch unit 54 while the high pressure to the CRT apparatus 10 is cut off. In addition to the deflection, the vertical deflection block 44 applies a vertical deflection signal to the vertical deflection coil 44a by the vertical synchronizing signal Vsync from the main signal processing unit 34, thereby providing the CRT apparatus 10. Since the vertical deflection is to be performed, the R / G / B color beam is radiated from the R / G / B electron gun of the CRT apparatus 10 by the voltage discharged from the smoothing capacitor C when the power is turned off. In addition, deflection by the horizontal and vertical deflection coils 18 and 44a is made with respect to the high-voltage residual current component applied to the anode electrode, and thus deflection is made with respect to the residual R / G / B color beams. Light beam spot phenomenon can be prevented.

Such horizontal and vertical deflections in the power-off state are executed for a predetermined time set in the timer 32. When the elapse of the time set by the timer 32 is notified, the microcomputer 30 causes the main signal processing unit 34 to perform the predetermined deflection. In addition to the control in the inactive state for the third switch unit 54 is also controlled in a non-connected state.

On the other hand, the present invention is not limited to the above-described embodiment, and the configuration does not deviate from the gist and the gist of the present invention as long as the structure enables vertical / horizontal deflection with respect to the remaining R / G / B color beams in the CRT apparatus when the power is turned off. It can be implemented in various ways.

As described above, according to the present invention, the residual light beam deflection control circuit of the CRT apparatus when the power is turned off, the residual R / G in the CRT apparatus under the control of the microcomputer when the power is turned off while the high pressure applied to the CRT apparatus is cut off. By deflecting the / B color beam over a predetermined time period, the light beam spot phenomenon of the CRT device can be prevented, and therefore, the specific part of the CRT device can be prevented from darkening, so that the life of the CRT device is relatively long. Can be achieved.

Claims (5)

The horizontal deflection coil 18 connected to the collector side of the horizontal output transistor 12 that switches in response to the horizontal drive signal to perform horizontal deflection of the CRT apparatus 10 and the vertical deflection of the CRT apparatus 10. In a television having a vertical deflection block 44 and a flyback transformer 20 which is commonly connected to the collector side of the horizontal output transistor 12 and generates a high voltage applied to the CRT apparatus 10, In response to the power ON / OFF by an external power control signal Pc, the control of applying high pressure to the horizontal deflection coil 18 and the CRT apparatus 10 and the deflection of the residual color beam of the CRT apparatus 10. A microcomputer 30 to control the; A timer (32) for setting a deflection period for the remaining color beams of the CRT apparatus (10) by the microcomputer (30); A main signal processor 34 which is activated during a deflection period with respect to the residual color beam under the control of the microcomputer 30 and generates a horizontal / vertical synchronization signal for deflection of the residual color beam; And deflection control means for performing horizontal deflection of the CRT apparatus 10 under the control of the microcomputer 30, wherein the residual light beam deflection control circuit of the CRT apparatus is turned off. 2. The first switch unit (40) of claim 1, further comprising a first switch (40) interposed between the horizontal output transistor (12) and one end of a primary coil of the flyback transformer (20). The second switch unit 42 interposed between the horizontal deflection coil 18 is provided for the high-voltage application control of the CRT apparatus 10 by the microcomputer 30, the power-off CRT Residual light beam deflection control circuit in the device. 2. The deflection control means according to claim 1, wherein the deflection control means responds to a horizontal synchronizing signal from the main signal processing section 34 which is activated and controlled by the microcomputer 30 when the power control signal Pc indicates power off. A horizontal transform transformer 48 connected to the switching first switching transistor 46 and a collector of the first switching transistor 46, in which a power source corresponding to the horizontal synchronous signal is induced on the secondary side thereof; A second switching transistor 50 which connects a base to a secondary power supply of the transformer 48 and switches, and a third switch section which sets a horizontal deflection path of collector current appearing in the collector of the second switching transistor 50 ( 54) and a decompression transformer 52 having one end of the primary side connected to the collector side of the second switching transistor 50 in common to obtain a power source reduced in pressure on the secondary side. Is the power of the CRT device off when the residual light beam deflection control circuit. The method of claim 3, wherein the third switch section 54 is the second switching transistor Interposed between the collector of 50 and one end of the horizontal deflection coil 18, when the power control signal Pc instructs to turn off the power, the first and second switch parts 40 and 42 act inversely. Connection control under the control of the microcomputer (30). 4. The residual light beam deflection control circuit of claim 3, wherein the primary coil of the decompression transformer has the same turns ratio as the primary winding of the flyback transformer (20).

Images