KR100216129B1 - Apparatus for controlling beam spot position of cathode-ray tube - Google Patents

Abstract

The present invention relates to a beam spot position changing apparatus of a CRT apparatus when power is cut off, during a high-pressure discharge period applied to the CRT apparatus 10 to change the position of the beam spot appearing in the CRT apparatus 10 when the power is cut off. The control unit 36 controls the generation of the vertical deflection signal with respect to the beam spot and switches the path of the vertical deflection signal, and the beam of the CRT apparatus 10 during the high pressure discharge period under the control of the control unit 36. The vertical deflection control unit 40 generating a vertical deflection signal for changing the position of the spot, and setting the path of the vertical deflection signal oscillated by the vertical deflection control unit 40 under the control of the control unit 36. And a switching unit 38 to be applied to the device 10, and vertically deflects a beam spot by the vertical deflection signal when the power is cut off, thereby concealing the upper and lower screens of the screen visible area of the CRT device 10. Language On one side.

Description

Beam spot position changing device of CRT unit when power is cut off

The present invention relates to a beam spot position changing device of a CRT device when the power is cut. More specifically, the vertical deflection current is not visually observed by synthesizing a beam spot phenomenon appearing in the center of the screen of the CRT device when the power is cut off. The screen of the CRT apparatus relates to a beam spot position changing apparatus of the CRT apparatus when the power is turned off so that the screen of the CRT apparatus is changed to a concealed area.

In general, the screen area of a CRT apparatus, which is mainly used as a means for reproducing a video signal in a television, generally includes a screen visible region in which a video signal is visually displayed, and a constant margin around the screen visible region. The non-visual screen formed by setting) is made of a closed area. According to the principle that the color image is reproduced in the screen region of such a CRT device, the R / G / B color beam is represented in the R / G / B electron gun corresponding to the R / G / B color component of the image signal processed from the image processing system. When the R / G / B color beam reaches the R / G / B fluorescent point formed on the fluorescent panel, the color image is reproduced while the R / G / B pixels corresponding to the R / G / B color beam emit light. Will be.

1 is a diagram schematically illustrating a power supply system of a television applied when a color image is reproduced by a CRT apparatus, and reference numeral 10 denotes an R / G / B that emits an R / G / B color beam corresponding to an image signal. A CRT device having an electron gun and a fluorescent panel is shown, and 12 denotes a horizontal output transistor which switches in response to a horizontal drive signal (Hds) having a constant duty ratio applied from a horizontal drive means (not shown). Denotes a diode and a capacitor provided for the damping action of the collector current appearing on the collector side during the switching action of the horizontal output transistor 12.

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. According 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, according to the power supply system of the television shown in FIG. 1, when the power is turned off, the power supply B + applied to the flyback transformer 20 is cut off, and the flyback transformer 20 has an image output power supply DC and a high voltage. (H · V) is not generated, but the power charged in the smoothing capacitor (C) for smoothing the image output power (DC) applied to the image processing unit 28 is applied to the image processing unit 28 and In addition, a residual component of high voltage (H · V) exists in the anode electrode of the CRT apparatus 10, and in this state, the state in which the R / G / B electron gun of the CRT apparatus 10 is heated by the heater is a predetermined time. Will last for a while. 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-described circumstances, and the position of the beam spot appearing at the center of the CRT apparatus when the power is turned off is displayed by changing the position of the screen of the CRT apparatus to the closed region by synthesizing the vertical deflection current. It is an object of the present invention to provide a beam spot position changing device of a CRT device when the power is turned off to exclude the effect on the visible region.

In order to achieve the above object, according to a preferred embodiment of the present invention is provided with a CRT device for reproducing a color image of the R / G / B color components processed by the image processing unit by the high voltage and the image output power applied from the flyback transformer In a television, the vertical deflection signal is controlled in addition to controlling the generation of the vertical deflection signal for the beam spot during a high-voltage discharge period applied to the CRT device to change the position of the beam spot appearing in the CRT device when the power is cut off. A vertical deflection control unit for generating a vertical deflection signal for changing the position of the beam spot of the CRT apparatus during the high-voltage discharge period under the control of the control unit; and a vertical deflection control unit under the control of the control unit. And a switching unit configured to set the path of the oscillation signal, which is oscillated at, to be applied to the CRT device. The source beam spot position changing device of a CRT device is provided with the block.

Preferably, according to the present invention, the vertical deflection control unit oscillates the front end waveform system for oscillating the front end waveform of the vertical deflection signal and the rear end waveform of the deflection waveform system and the vertical deflection signal for oscillating the vertical deflection waveform of the beam spot. And a vertical deflection signal synthesizing unit for synthesizing the front end waveform, the vertical deflection waveform, and the rear short waveform to form the vertical deflection signal, wherein the beam spot is generated by the vertical deflection signal. The change position is set to either one of the closed area and the upper and lower screen areas of the screen visible area of the CRT apparatus.

According to the beam spot position changing apparatus of the CRT apparatus according to the present invention having the above-described configuration, the vertical spot current is synthesized during the high-pressure discharge time even when the power supply of the television is cut off so that the beam spot position is displayed on the screen of the CRT apparatus. The invisible screen above or below the area is changed to a closed area so that the screen visible area of the CRT apparatus is protected from the effects of the beam spot.

1 is a view schematically showing a power supply system of a television for explaining the principle that a beam spot phenomenon occurs in a conventional CRT apparatus;

2 is a block diagram of a television to which a beam spot position changing apparatus of a CRT apparatus is applied when a power is cut according to the present invention;

3 is a block diagram showing an example of the configuration of the vertical deflection control unit shown in FIG.

4 is a waveform diagram illustrating the operation of the beam spot position changing apparatus of the CRT apparatus when the power is cut according to the present invention.

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

10: CRT device, 28: image processing unit,

32: synchronization signal separation unit, 34: vertical deflection unit,

36: control unit, 38: switching unit,

40: vertical deflection control unit

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

2 is a view showing a beam spot position changing device of the CRT apparatus when the power is cut according to a preferred embodiment of the present invention, Figure 3 is a block diagram showing an example of the configuration of the vertical deflection control unit shown in FIG.

In the figure, reference numeral 30 denotes an image IF signal by converting a broadcast signal of a channel tuned from a tuner to a predetermined intermediate frequency to obtain an image IF signal, which is processed by the image processing unit 28 as an R / G / B color component, and thereby the CRT apparatus 10. 32 denotes a synchronization signal separation unit which separates a horizontal synchronization signal from the image IF signal to provide a horizontal / vertical deflection signal for the CRT apparatus 10, and 34 In the power supply state of the corresponding television, the vertical deflection is performed on the CRT apparatus 10 based on the vertical deflection signal oscillated on the basis of the horizontal synchronization signal separated by the synchronization signal separation unit 32 while the power is cut off. Denotes a vertical deflection portion in which vertical deflection is performed with the beam spot position changed according to the present invention.

In FIG. 2, reference numeral 36 denotes a remote control signal from a remote controller, and when the power ON signal is input, oscillates based on the horizontal synchronization signal separated from the synchronization signal separator 32 while controlling the normal operation of the corresponding television. The high pressure of the CRT apparatus is discharged in a state in which the beam spot position according to the present invention is changed when the path for controlling the horizontal / vertical deflection of the CRT apparatus 10 is made by the horizontal / vertical deflection signal or when the power is cut off. A control unit for switching control (SW) the switching unit 38 to control the path for the vertical deflection to be performed during the period is shown.

Further, 40 is provided in accordance with the present invention and is activated under the control of the control unit 36 when the power is cut off to oscillate a vertical deflection signal during the high-voltage discharge period of the CRT apparatus, thereby causing the vertical deflection unit 34 to pass through the switching unit 38. Indicates a vertical deflection control unit to be applied.

3 is a block diagram showing an example of the configuration of the vertical deflection control unit 40. According to the present invention, the vertical deflection control unit 40 is a screen visible area of the CRT apparatus 10 when the power is turned off. The screen set at the bottom of 10a) in the a) to the frontal waveform system and the actual deflection for oscillating the tip waveform of the vertical deflection signal so that the position of the beam spot is set in the closed area (Fig. 3 (a) to 10b). And a deflection waveform system for oscillating the deflection waveform of the vertical deflection signal and a trailing waveform system for oscillating the trailing waveform of the vertical deflection signal.

The first waveform system for oscillating the tip waveform of the vertical deflection signal applied when the power is cut off is activated by the control signal EN from the controller 36 to oscillate the first reference waveform in the form of a sawtooth wave. A first duty converter 422 for converting the duty ratio of the waveform generator 420 and the first reference waveform oscillated by the first reference waveform generator 420 to be equal to the vertical synchronization signal; And a first timing adjustment unit 426 for timing adjustment of the first reference waveform to be located in the vertical scanning period of the CRT apparatus 10. In addition, the trailing waveform system oscillating the trailing waveform of the vertical deflection signal includes an edge inversion unit 430 for inverting the edge direction of the first reference waveform oscillated by the first reference waveform generator 420, and the edge thereof. The second duty converter 432 converts the duty ratio of the first reference waveform edge-inverted by the inverter 430 to be equal to the vertical synchronization signal, and converts the duty-converted waveform into the first amplifier 424. Timing of the second amplifier 434 to amplify at the same amplification rate and the waveform signal amplified by the second amplifier 434 to be suitable for the vertical scanning period (especially the vertical retrace period) of the CRT apparatus 10. And a second timing adjustment unit 436 for adjustment. In addition, the deflection waveform system of the vertical deflection signal preferably includes a second reference waveform generator which generates a square wave having the same period as the first reference waveform generated by the first reference waveform generator 420 as a second reference signal. 440 and a third duty converter 442 for converting the second reference waveform generated by the second reference waveform generator 440 into a duty ratio corresponding to the vertical scanning period of the CRT apparatus 10. And a third amplifying part 444 for amplifying the signal of the duty-converted waveform, and a third timing adjusting part 446 for adjusting the amplified signal of the waveform to the actual scanning time of the vertical scanning period.

In addition, the vertical deflection control unit 40 synthesizes a front end waveform part, a deflection waveform part, and a rear end waveform part of the vertical deflection signal applied by the first to third timing adjustment parts 426, 436, and 446 to turn off the power. A vertical deflection signal synthesizing portion 450 is included for changing the beam spot position of the vertical deflection signal synthesizing portion 450. The vertical deflection signal synthesizing portion 450 preferably comprises a front end waveform portion, a deflection waveform portion and a rear end waveform portion of the vertical deflection signal. Consists of OR gates for OR processing.

Next, the operation of the beam spot position changing apparatus of the CRT apparatus when the power is cut according to the present invention having the above-described configuration will be described in detail with reference to FIG.

First, when a power ON signal is applied from the remote control unit to the control unit 36, the power supply system shown in FIG. 1 is activated under the control of the control unit 36, and the corresponding television is operated. In this state, the control unit 36 ) Applies a switching control signal SW to the switching unit 38 so that a path is set to the synchronization signal separating unit 32.

Then, under the control of the control unit 36, the broadcast signal RF of the channel tuned from the tuner is applied to the image IF module 30, converted by a predetermined intermediate frequency, and applied to the image processing unit 28. Accordingly, the image processor 28 applies the R / G / B color component obtained by processing the image signal to the CRT apparatus 10. In addition, a horizontal synchronizing signal separated from the image IF signal of the image IF module 30 by the synchronization signal separator 32 is applied to the vertical deflection unit 34 through the switching unit 38 to FIG. A vertical deflection signal of the type shown in b) is obtained, and the vertical deflection signal is applied to the vertical deflection system of the CRT apparatus 10 to generate an R / G / B color beam generated by the CRT apparatus 10. Vertical deflection is performed. Therefore, in the CRT apparatus 10, a color image is reproduced on a screen area including a screen visible area 10a and a screen concealment area 10b around the screen center portion T1 shown in FIG. 4 (a). do.

When the power-off signal is applied to the control unit 36 from the remote control in the operating state of such a television, the power supply system shown in FIG. 1 is deactivated, but the control unit 36 during the high-pressure discharge period applied to the CRT apparatus. The switching unit 38 is switched to the vertical deflection control unit 40 based on the standby power source ST, and the first reference waveform generating unit 420 and the second reference of the vertical deflection control unit 40 are switched. The activation control signal EN is applied to the waveform generator 440 to control to generate a vertical deflection signal for changing the beam spot position of the type shown in FIG.

Accordingly, the first amplification waveform (generally sawtooth waveform) generated by the first reference waveform generator 420 is duty-converted so as to be equal to the period of the vertical synchronization signal in the first duty converter 422 and then the first amplification. The signal of the waveform applied to the unit 424 and amplified by the first amplifier 424 is shown in FIG. 4 (d) in the first timing adjusting unit 426, that is, as shown in FIG. 4 (c). Adjustment is performed at a timing corresponding to the tip waveform portion t1 of the vertical deflection waveform, and then applied to the vertical deflection signal synthesis section 450. In addition, the first reference waveform generated by the first reference waveform generator 420 is subjected to the edge inversion processing at the edge inversion unit 430 and then applied to the second duty converter 432 to be equal to the period of the vertical synchronization signal. The duty-converted waveform is applied to the second amplifier 434 to amplify the signal. The signal of the amplified waveform is shown in FIG. The adjustment is made at the timing corresponding to the shape, that is, the rear end waveform portion t3 of the vertical deflection waveform shown in Fig. 4C, and then applied to the vertical deflection signal synthesis section 450. In addition, the second reference waveform of the square wave oscillated at the same period as the first reference waveform by the second reference waveform generator 440 corresponds to the interval between the syringes of the vertical synchronization signal in the third duty converter 442. After the duty conversion, the signal is applied to the third amplifier 444 and amplified, and the signal of the amplified waveform is applied to the third timing adjusting unit 446 to form the form shown in FIG. ) Is adjusted to a timing corresponding to the deflection waveform portion t2 of the vertical deflection waveform and is applied to the vertical deflection signal synthesis unit 450.

Accordingly, the vertical deflection signal synthesis unit 450 performs logical OR processing on the waveforms shown in FIGS. 4 (d), (e), and (f) applied by the first to third timing adjustment units 426, 436, and 446. The vertical deflection waveform shown in (c) is generated, and the vertical deflection waveform is controlled through the switching unit 38 which is switched to the vertical deflection control unit 40 when the power is cut off under the control of the control unit 36. It is applied to the vertical deflection portion 34 to act as a vertical deflection signal of the CRT apparatus 10 when the power is cut off. Then, the R / G / B color beams due to the high pressure remaining in the CRT device 10 are vertically deflected to the closed area 10b of the lower screen of the CRT device 10 shown in FIG. Accordingly, when the power is cut off, the beam spot does not appear in the screen visible area 10a of the CRT apparatus 10.

4 (c), the lower screen of the CRT apparatus 10 performs vertical scanning so that the beam spot is located in the closed area 10b. However, the vertical deflection waveform shown in FIG. When the illustrated vertical deflection waveform is inverted in the form of the waveform shown in FIG. 4 (g), when the power is cut off, the beam spot appears to be vertically deflected to the closed screen 10a of the upper screen of the CRT apparatus 10.

As described above, according to the beam spot position changing apparatus of the CRT apparatus when the power is cut off, a vertical deflection signal is generated during the high-voltage discharge period remaining in the CRT apparatus when the power is cut off, so that the vertical deflection with respect to the CRT apparatus is reduced. By doing so, the beam spot appearing in the visible region of the CRT apparatus can be changed to the closed region in the upper or lower screen, thereby eliminating the beam spot appearing in the visible region of the CRT apparatus when the power is turned off. It is possible to shorten the life of the screen visible area.

Claims (7)

In a television equipped with a CRT apparatus (10) for reproducing a color image of an R / G / B color component processed by an image processing unit (28) by a high voltage applied from a flyback transformer and an image output power source. In addition to controlling the generation of a vertical deflection signal for the beam spot during the high-pressure discharge period applied to the CRT device 10 to change the position of the beam spot appearing in the CRT device 10 when the power is cut off. A control unit 36 for switching the path of the deflection signal; Vertical deflection control unit 40 for generating a vertical deflection signal for changing the position of the beam spot of the CRT apparatus 10 under the control of the control unit 36, Under the control of the control unit 36, the power supply characterized in that it comprises a switching unit 38 for setting the path of the vertical deflection signal oscillated by the vertical deflection control unit 40 to be applied to the CRT apparatus 10 CRT device beam spot repositioning device when shut off. The vertical deflection control unit 40 is a front end waveform system for oscillating the front end waveform of the vertical deflection signal and a rear end of the deflection waveform system and the vertical deflection signal for oscillating the vertical deflection waveform of the beam spot. CRT for power off, characterized in that it comprises a rear waveform system for oscillating a waveform, and a vertical deflection signal synthesizing portion 450 for forming the vertical deflection signal by synthesizing the front waveform with the vertical deflection waveform and the rear waveform. Beam spot repositioning device for the device. The first reference waveform generator 420 of claim 2, wherein the tip waveform system is activated by a control signal EN from the controller 36 to oscillate a first reference waveform having a sawtooth wave shape. A first duty converter 424 for converting the duty ratio of the first reference waveform oscillated by the first reference waveform generator 420 to be equal to a vertical synchronization signal, and converting the duty converted first reference waveform into the CRT apparatus And a first timing adjusting section (426) for timing adjustment so as to be positioned in the vertical scanning period of (10). [3] The edge waveform generator of claim 2, wherein the trailing waveform system comprises an edge inverting portion 430 for inverting an edge direction of the first reference waveform oscillated by the first reference waveform generating portion 420, and an edge inverting portion 430 thereof. The second duty converter 432 converts the duty ratio of the edge-inverted first reference waveform to be equal to the vertical synchronization signal, and amplifies the duty-converted waveform at the same amplification factor as that of the first amplifier 424. And a second timing adjusting section 436 for timing adjustment of the waveform signal amplified by the second amplifying section 434 so as to be suitable for the vertical retrace period of the CRT apparatus 10. Beam spot position changing device of the CRT device when the power is cut off. The method of claim 2, wherein the vertical deflection waveform system is a second reference waveform generator 440 for generating a square wave as a second reference signal and the second reference waveform generated by the second reference waveform generator 440 A third duty converter 442 for converting the duty ratio corresponding to the vertical scanning period of the CRT apparatus 10, a third amplifier 444 for amplifying the duty-converted waveform signal, and a signal of the amplified waveform. And a third timing adjustment unit (446) for adjusting the time to the actual scanning time of the vertical scanning period. 3. The OR of claim 2, wherein the horizontal deflection signal synthesizing unit 450 performs an OR for logic OR processing of the front end waveform part, the deflection waveform part, and the rear end waveform part of the vertical deflection signal applied by the first to third timing adjusting parts 426, 436, and 446. Beam spot position changing device of the CRT device when the power is cut off, characterized in that consisting of a gate. 7. The screen of any one of claims 1 to 6, wherein the change position of the beam spot due to the vertical deflection signal at the time of power interruption is either one of an upper and lower screen concealment areas of the screen visible area of the CRT apparatus 10. Beam spot position changing device of the CRT device when the power is cut off.

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