KR800000781B1 - Power supply for a television receiver - Google Patents

Abstract

A television receiver is equipped with a power supply including a 1st. inductor with predetermined inductance and a 2nd. inductor coupled magnetically with the 1st, inductor. The 2nd. inductor provides a deflection oscillator(84) with a 2nd. A. C. electric potential higher than the 1st. selected one. It is characterized that when the inductance of the 1st. inductor drops below the predetermined inductance, the 2nd. A. C. electric potential drops below the predermined 1st. one so that the kinescope(460) & the deflection oscillator(84) may not operate.

Description

Power source for television receiver

1 is a partial schematic of a television receiver.

2A and 2B are waveform diagrams of current and voltage at various points in the schematic diagram of FIG.

FIG. 3 is a series of curve diagrams showing the mutual change relationship at two threshold voltages of the schematic diagram of FIG. 1. FIG.

4 through 6 illustrate various embodiments of a part of the deflection circuit and signal of FIG.

The present invention relates to a power supply for a television receiver.

Various power supply circuits have been used in television receivers. One circuit of these power supplies utilizes a rectifier that will be connected to an AC voltage source to provide a pulsed DC voltage. The chocolate input filter, connected to the rectifier, provides a DC voltage with a suitable pulsation rate, for example, for a circuit used to generate the high voltage required at the ultor (high voltage) electrode of a kinescope tube.

In this case, the choke input filter is often used instead of the capacitor input filter for the following reasons.

(1) A low pulsation rate DC voltage with an amplitude less than the peak voltage of the AC converter is generated without power transformer and large power loss.

(2) The DC voltage is kept relatively constant over a predetermined range of the load current.

(3) DC voltage is not related to filter capacitor capacity. However, the chocolate input filter has one disadvantage. That is, if the choke inductance is reduced by an external choke short circuit or winding short circuit which causes a rise in the DC voltage provided at the output of the choke input filter, the high voltage of the kinescope is increased without the image of the kinescope being lost. Is leaked out and the viewer may be exposed to excessive X-ray radiation of 0.5 mR / hr (HEW). However, if the choke inductance is below the selected level, if the image is not played on the kinescope, then the viewer should not be encouraged to operate the television receiver continuously but to protect the viewer from increased X-ray radiation.

A television receiver power supply comprising an apparatus for displaying visibility images on a kinescope includes a stop connected to the first alternating current source to generate a pulsed direct current potential. A device including a first inductor connected to a stop and a device for displaying a visibility image provides a device for screening a visible image by filtering a pulsed DC potential. The first inductor provides a relatively constant level of direct current potential and a relatively constant level of pulsed direct current potential to a device having a selected inductance value and displaying a visible image. The second inductor magnetically coupled to the first inductor and coupled to the device for displaying the visible image provides a second alternating potential greater than the selected level to the device for displaying the visible image. When the inductance of the first inductor is reduced to a value smaller than the inductance value selected so that the kinescope is invisible, the second alternating potential level decreases to a level below the selected level.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

In FIG. 1, an alternating voltage source (not shown) is connected to terminals P and Q of bridge rectifier 12. Bridge rectifier 12 and terminal S are connected to the reference potential point. The pulsed dc potential flows out between terminal R of the bridge rectifier 12 and the reference potential. The choke input filter 14 includes a series connection of the filter capacitor 18 and the choke coil 16 connected between the terminal R and the reference potential, and a series connection of the filter capacitor 22 and the resistor 20 connected between the contact of the filter capacitor 18 and the reference potential. The contact of resistor 20 and filter capacitor 22 provides the filtered dc conductor (B ++).

Choke coil 16a provides a relatively constant level of B ++ over a predetermined range of direct current flowing through the reference potential with a relatively constant amplitude alternating potential applied from B ++ to bridge rectifier 12.

The signal processing and deflection system 26 includes a horizontal oscillator 32 which outputs a signal at an output terminal connected to the horizontal deflection output circuit 30, so that the current flowing from the B ++ to the reference potential through the windings 24a and 24b of the deflection output circuit 30 and the high voltage transformer 24. To control. The first terminal of winding 24c is connected to the reference potential and the other terminal is connected to terminal 38 so that a horizontal retrace pulse flows out of terminal 38 with respect to the reference potential during operation.

The pulse shown at terminal 38 is applied to and rectified by the high voltage rectifier 40 to generate a high voltage direct current potential at the output terminal 42 of the high voltage rectifier 40. The output terminal 42 is connected to the ulter electrode 44 of the kinescope tube 46, thereby accelerating the electron beam generated in the kinescope tube 46 to a predetermined degree.

The pulse generated at the junction of windings 24a and 24b is connected to terminal 48 via an S-type capacitor 36. Terminal 48 is connected to the reference potential via horizontal yoke windings 50a and 50b. The current flowing through the yoke windings 50a and 50b horizontally deflects the electron beam in the kinescope tube 46.

The waveforms of the current through the choke coil 16a under the various conditions shown as I ₁ in FIG. ₁ are shown in FIG. 2a. Also shown in FIG. 2a is the average load current from B ++, shown as I ₂ in FIG. Waveform 70 shows current I ₁ when the inductance of choke coil 16a is much larger than the minimum inductance determined by the following formula L _MIN = R _L / 6πf _AC line. Waveform 72 shows a slightly decreasing current I ₁ in the inductance of choke coil 16a (ie a shorted very small winding) but its inductance is greater than L _MIN . Waveform 74 shows current I ₁ when the inductance of choke coil 16a is less than L _MIN (ie, a very short shorted winding). Due to the inductance smaller than L _MIN , the current through coil 16a is zero for a certain interval as shown in waveform 74.

Since the inductance of choke coil 16a is greater than L _MIN , the voltage generated across winding 16b is represented by waveform 76 in FIG. 2B. When the value is reduced to less than the inductance L _MIN of the choke coil 16a, the peak-to-peak amplitude of the voltage generated across the winding 16b decreases. Waveform 78 shows one peak-to-peak voltage state across winding 16b when the inductance of choke coil 16a is reduced below L _MIN .

FIG. 3 shows the correlation of the voltage change across winding 16b with a change in B ++ and a degree of decrease with decreasing inductance of choke coil 16a. Curve 80 shows the effect of varying degrees of reduction in the inductance of the choke coil 16a on the positive peak of the voltage generated across the winding 16b. Curve 82 shows the effect of the RMS voltage generated by winding 16b with various variations in the inductance of choke coil 16a.

Curve 84 shows the reduction of the negative peak of voltage generated by winding 16b with various decreases in inductance of choke coil 16A.

Winding 16b is connected to the signal and deflection circuit 26 and how the specific characteristics of the voltage generated by the winding 16 (ie, the positive peak, the RM.S voltage and the negative peak) are described in relation to the fourth to sixth degrees. Provides proper operation of deflection circuit 26 and various segments of the signal in case of exceeding the selected level.

If B ++ will be generated and the voltage generated by the winding 16b exceeds the predetermined level, vertical deflection signals are generated at the output terminal 52 of the signal and deflection circuit 26 and the current through the vertical deflection windings 54a and 54b. By providing a flow, it provides a horizontal deflection of the electron beam generated by the kinescope tube 46. Voltages are also generated at terminals 56, 58, 60, 62, 66 and 68, which provide some beam current in the kinescope tube 46.

Electron beam current modulation in the kinescope tube 46, connected to the antenna 64 and connected to the signal and deflection circuit 26, to provide the desired optical density modulation on the screen of the kinescope 46 to reproduce the image information contained in the composite video signal. Provides modulation of the voltage at terminals 66 and 68 required to generate

4 is a schematic diagram of a first embodiment of a part of the signal and deflection circuit 26 shown in FIG. The first electron of the winding 16b is connected to the reference potential and the other terminal of the winding 16b is connected to the anode of the diode 80. The cathode of diode 80 is connected via filter capacitor 82 to the reference potential. The cathode of diode 80 provides a direct current conductor (B +).

The cathode of the diode 80 is connected to a deflection oscillator 84 which comprises transistors 86, transistor 88, transistor 90, and transistor 92, the transistors of which are at the terminal 94 the vertical deflection circuits of the signal and deflection circuits 26 and the horizontal deflection circuits. It provides a drive signal for driving one of the.

The proper phase of the signal at output terminal 94 is formed by the device of the synchronization signal branching from the composite video signal and connected to the synchronization input terminal 96. By properly selecting the component values associated with the transistors 86-92, the deflection oscillator 84 stops the generation of the signal at terminal 94 or stops the deflection output circuit if the voltage generated by the winding 16b drops below a predetermined level. The driving force is formed so as not to drive. If no signal is present or if the signal does not provide sufficient driving force, the kinescope does not display an image.

FIG. 5 is a second embodiment of 26 portions of the signal and deflection circuit shown in FIG. B + is provided by the rectification of the voltage generated by winding 16b in the same way as shown in FIG. However, in the case where the voltage generated by the winding 16b is enhanced below the predetermined level, B + is utilized in other ways so that the kinescope 46 does not display an image. B + is supplied to video intermediate frequency amplifier 98 and video amplifier 100. In the case where the voltage generated by the winding 16b is strengthened below the predetermined level, the level of B + becomes insufficient voltage than the voltage for normal operation of the intermediate frequency amplifier 98 and the video amplifier 100. Therefore, since the signal applied to the intermediate frequency input terminal of the intermediate frequency amplifier is not supplied to the kinescope 46 in FIG. 1 in place of the video output terminal through the intermediate frequency amplifier and the image amplifier, the kinescope 46 does not display the image.

FIG. 6 is a third embodiment of 26 parts of the signal and deflection circuit shown in FIG. Winding 16b is connected to terminals 60 and 62 of signal and deflection circuit 26. Terminals 60 and 62 are connected to the filament of kinescope tube 46 to heat the cathode electrode, thereby facilitating the release of electrons from the cathode surface and increasing the flow of beam current in kinescope tube 46. Since the inductance of the choke winding 16a decreases below L _MIN , B ++ is increased as shown in Figure 3, thus increasing the high voltage provided at the output terminal 42 of the high voltage rectifier 40 and at the ulter electrode of the kinescope 46. Increase the pulse width at the triggering signal and the terminal 38 of the deflection circuit 26. Increasing the ultor electrode voltage having a predetermined radiation level from the cathode of the kinescope or 46 increases the X-ray radiation generated by the kinescope tube. By coupling the winding 16b to the filament of the kinescope tube, the voltage is increased by the reduction of the inductance with the choke coil 16a, so the voltage provided by the winding 16b decreases B ++, thus reducing the temperature of the cathode of the kinescope 46 and Reduces the beam current in the 46. By proper selection of the operating conditions of the circuit elements of FIG. 6 and the kinescope tube 46, the X-ray emission from the kinescope tube 46 can be kept below the threshold level.

As can be seen from the analysis of various embodiments of the present invention, the kinescope 46 is reduced when the inductance of the choke coil 16a is reduced by an element that causes the increase of the high voltage applied to the ultor electrode 44 (i.e., a short circuit of the winding). No image is displayed. In the presence of these elements, the kinescope does not display an image, so that the viewer turns off the television receiver, thereby reducing the viewer's exposure to excessive X-ray radiation.

Claims (1)

As described herein and illustrated in the figures, an apparatus for displaying a visible image on a kinescope comprising a deflection oscillator, a stop connected to a first source of alternating current potential to outflow a pulsed direct current potential, and A device comprising one inductor and connected to said device for screening visibility images to provide said first source of direct current potential to said device for screening said stop and visibility images, and to said device for screening visibility images A first constant inductor having a predetermined range of direct currents and a relatively constant level of pulsed direct current potentials, the first inductor having a predetermined inductance size, and a magnetic coupling to the first inductor. In a television receiver having a power supply comprising two inductors, the second inductor is less than the first selected level. Providing a second alternating potential to the deflection oscillator, wherein when the inductance of the first inductor is reduced below a predetermined inductance size, the first and second inductors are mounted so that the second alternating potential level is reduced Power supply for a television receiver, characterized in that the scope is reduced to a level below the selected first level such that the oscillator is inoperative and the deflection oscillator is inoperative.

Images