KR810002134B1 - Inrush current starting circuit for television receivers containing starting decoupling circuit - Google Patents

Abstract

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Description

Inrush current starting circuit for television receivers containing starting decoupling circuit

1 is a circuit diagram of a television receiver containing a starting circuit according to the present invention.

2 and 3 are waveform diagrams relating to the circuit of FIG.

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

The rectified AC line voltage is filtered and adjusted to supply a high B + operating voltage to the television receiver. The high B + may, for example, be connected to a horizontal deflection circuit to generate a scan current in the horizontal deflection winding. The low B + voltage must be supplied as an operating voltage to various receiver circuits such as the oscillator and drive stage of the horizontal deflection circuit itself. It is desirable to derive a low B + voltage from the secondary winding of the horizontal output transformer to insulate the line voltage from the television pedestal after the horizontal deflection circuit begins to operate. However, during the initial startup period after the receiver is turned on, no low B + voltage is generated by the horizontal output transformer to operate the drive stage of the oscillator and the horizontal deflection circuit. Another supply of low B + voltage must be supplied during this initial startup period.

A method of supplying a low B + starting voltage is described, for example, in US Pat. The AC line voltage is rectified to supply a high B + voltage. When the receiver is turned on, the starter circuit increases the low B + start operating voltage for a television receiver circuit such as the horizontal deflection circuit.

After a predetermined period has elapsed, the horizontal deflection circuit itself will supply the low B + operating voltage. The starting circuit is stopped, thereby decoupling the starting circuit from the television receiver circuit.

In US Pat. No. 3,968,332, the device is quite bulky and expensive because it derives an almost low B + starting operating voltage from the anti-magnetic coil. Moreover, in some cases, the inrush of the current is not complete until the end of the self-protection period, and therefore the horizontal oscillator does not operate when the horizontal output is activated.

In addition, the apparatus of US Pat. No. 39,476,32 cannot be used in television receivers that do not use a magnetic barrier coil, such as a single chroma receiver.

According to the above-described embodiment of the present invention, the starting power source for the television receiver contains a primary stop value responsive to a power source of a primary AC potential for vibration DC voltage supply, and a primary stop value for primary DC voltage supply. It contains a filter device connected to it. Inrush currents flow into the filter device during the initial period. This embodiment contains a load circuit and a secondary stop connected to generate a primary operating voltage for the load circuit during the initial period. The secondary device is connected to the load circuit for supplying the secondary operating food to the lead circuit for replacing the primary operating voltage during a fixed period of time. The primary winding is connected to the filter device in the inrush current. The devices are connected to the primary winding and respond to an inrush current to increase the secondary alternating potential during the initial period. The device connects a tertiary voltage to the secondary rectifier. The tertiary voltage is changed to various values from the initial period to the fixed state period in the same manner as the supply method for decoupling the secondary AC potential from the load circuit during all the periods of the fixed state.

In FIG. 1, the 120 volt 60-held AC line voltage or other alternating current obtained at 21 characters is applied to the bridge rectifier 23 and the input terminals 24 and 25 through the ON and OFF switches 70 and the current limiting resistor 22. Connected. The output terminal 26 of the bridge rectifier 23 is connected to one of the ends of the main filter capacitor 28 through the primary winding 29 of the transformer 29. The other end of the capacitor 28 is connected to the feedback terminal 27 of the rectifier 23, which specifies the ground reference potential which is not insulated from the AC line, drift current.

The rectified DC voltage flowing through capacitor 28 is connected to the B + voltage regulator 30, which is designed in a conventional manner and supplies the regulated high B + operating voltage indicated at terminal 31, the high B + operating voltage being + It is shown to be well described as 110 volts.

The high B + operating voltage is connected to the primary winding 32a of the horizontal output transformer 32 of the horizontal deflection circuit 33 of the television receiver. The horizontal deflection circuit 33 includes a horizontal oscillator 34, a horizontal drive transistor 35 attached to the filter elements 36-38, a coupled transformer 39, a horizontal output circuit 40, a horizontal output transformer 32, and the like.

The horizontal output circuit 40 is composed of a horizontal output transistor 41, a braking diode 42, a horizontal deflection winding 44 connected in series with a sweep line capacitor 43, an S-type capacitor 45, and the like. The secondary winding of the connecting transformer 39 is connected across the base and emitter of the horizontal output transistor 41 via the network 46 constituting elements 47-51 and forming filters and waveforms.

Although not shown, the tertiary winding 32 of the horizontal output transformer 32 is connected to the high voltage circuit 52 to supply the high voltage acceleration potential shown at terminal U to the high voltage line of the cathode ray tube.

After the horizontal deflection circuit 33 is started to operate, the horizontal retrace and sweep line voltages appear through the secondary winding 32 and the secondary winding 32 of the horizontal output transformer 32, and although not shown, each terminal 55 and 56 for various television receiver circuits. It is rectified by diodes 53 and 54 to supply a low B + operating voltage of +27 volts and -30 volts shown. Each end of the secondary windings 32c and 32d is connected to a ground reference potential insulated from an AC line such as a television receiver pedestal. Diode 53 rectifies the voltage through winding 32c during retrace, and capacitors 57 and 58 and doctor 59 filter the +27 volt operating voltage. Diode 54 rectifies the voltage through winding 32d during retrace, and the anode of diode 54 is connected to capacitor 60 through resistor 99 to supply a rectified -30 volt operating voltage. The +27 volt voltage shown at terminal 55 is connected to a +22 volt regulator 61, which is designed in a conventional manner to supply a +22 volt operating voltage to terminal 62.

The low B + operating voltage for the horizontal deflection circuit itself is also supplied by the horizontal output transformer 32. The +27 volt voltage shown at the cathode of diode 53 is connected to the collector of horizontal drive transistor 35 through diode 63, filter element 64-66, and the primary winding of coupling transformer 39. The +22 volts from terminal 62 is supplied to horizontal oscillator 34 via diode 67. Connected to the cathode of diode 67 is filter capacitor 68.

When the television receiver is first operated, the horizontal deflection circuit 33 is stopped after the unloading or after switch 70 is connected, and then any low B + operating voltage is not useful, so the capacitor 28 of the main filter must be charged. . Another voltage source of low B + operating voltage for starting the horizontal deflection circuit must be supplied.

Secondary winding 29b is autonomously connected to primary winding doctor 29a. One end of the secondary winding 29 is connected to the common junction of the anodes of diodes 69 and 71. The cathode of diode 69 is connected to the cathode of diode 67, and the cathode of diode 71 is connected to the cathode of diode 63. The remaining end of secondary winding 29b is connected to a -30 volt terminal 56.

The main filter capacitor 28 is initially discharged. In the initial period, after the after switch 70 is connected, a large inrush current flows through the rectifier 23 to charge the capacitor 28 to its fixed value. This inrush current also flows through the primary winding 29a of the transformer 29. The alternating potential is increased through the secondary winding 29 during this initial rush. This AC potential is rectified by diodes 69 and 71 and provides a low B + operating voltage for start-up during the early inrush period sufficient for use by horizontal oscillator 34 and horizontal drive transistor 35.

The horizontal deflection circuit 33 will then begin to operate, and the horizontal output transformer secondary winding 32c will supply a low B + operating voltage of +27 volts to the cathode of diode 53 after the initial inrush period.

During stationary operation, main filter capacitor 28 is charged to its stationary DC voltage, diodes 69 and 71 are reverse biased, and the horizontal output transformer secondary winding 32c and its rectifiers and filters are fixed for the horizontal deflection circuit. Status Provide a low B + operating voltage.

It is a feature of the present invention to confirm that diodes 69 and 71 remain reverse biased during all fixed periods, so that the decoupling alternating current potential appears from the horizontal deflection circuit through the secondary winding 29b of the transformer 29. will be. This result is achieved by connecting secondary winding 29b to -30 volt terminal 56. Therefore, -30 volts is obtained from the horizontal output transformer secondary winding 32d, and the voltage shown at terminal 56 increases from zero volts appearing at the beginning of the turn-on of the receiver to -30 volts during fixed operation, therefore diode 69 and The reverse bias state of 71 is confirmed.

For example, as shown by the dashed line in FIG. 1, it is conceivable to connect one end of winding 29b to a constant voltage point, such as insulated ground, instead of connecting the end to -30 volt terminal 56. Because of the inrush current flowing in primary winding 29a, the alternating potential will be increased through secondary winding 29b during the initial time period T ₁ to T ₃ , as indicated by voltage 101 of FIG. The voltage is displayed. After the first initial pulse, diode 69 is only conductive near the peak of both pulses of voltage 101.

As the horizontal deflection circuit 33 starts to operate, its circuit elements, mainly the horizontal drive transistor 35, present the load on the filter capacitors 64, 65 and 68 and the transformer 29. Voltage 102 begins to decrease to an average value from time T ₁ to T ₂ . After the time T ₂ , the horizontal deflection circuit 33 operates for a long time so that the horizontal output transformer secondary winding 32c charges the filter capacitors 64 and 65 through diodes 53 and 63 to +27 volts, and from time T ₂ to T Start charging the filter capacitor 68 through the +22 volt regulator 61 and diode 67 as indicated by voltage 102 up to _three . Diodes 63 and 67 operate to decouple the load circuits connected to +27 volts and +22 volt terminals 55 and 62 from secondary winding 29b of transformer 29 during the initial period.

After a time T ₃ , during the stationary period, an important alternating potential is present in the secondary winding 29b due to the ripple current flowing through 29a which continues to charge the main filter capacitor 28 at a 120-held rate. Therefore, the ripple current also changes from the maximum value to the zero value at the 120 health ratio point, and generates a relatively large magnetic flux change and an induced voltage in the secondary winding 29b.

For some television receivers, for example, a television receiver with a relatively low β horizontal output transistor requires a relatively large drive current from the horizontal drive transistor, and transformer 29 has a relatively large load on the horizontal deflection circuit 33 during the initial inrush period. Power must be supplied. The design factor of transformer 29, i.e. its rotation rate, and mother-of-pearl coupling, for example, the voltage dropped by the horizontal drive transistor 35 during time T ₁ to T _3, for example the voltage below the minimum value required for operating the horizontal deflection circuit 33. In order not to reduce the voltage, relatively large voltage pulses must be supplied.

The criterion must be met to result in a relatively large amount of voltage pulses for voltage 101 during the fixed state period. In practice, both stroke peak values of voltage 101 exceed +22 volts, and the forward bias diode 69 in proximity to the peak voltage strokes and the ripple voltage 102a introduced into the +22 volts complement the horizontal oscillator 34. Such ripple would be added to the +22 volts required for regulator 61 to produce and produce the undesirable distortion of the raster. In other words, if the fixed state output of transformer secondary winding 29b exceeds the +27 volt peak value, pseudo ripple will appear through capacitors 64 and 65 together.

In order to eliminate the ripple caused by the fixed state alternating potential, winding 29b is connected to the -30 volt terminal 56 without being connected to ground as shown in FIG. The voltage shown at terminal 56 is zero for most of the initial inrush period as shown in FIG. 3 by voltage 103 from time T ₁ to T ₂ ′. After time T ₂ ′, as horizontal deflection circuit 33 continues to operate, voltage 103 begins to decrease to −30 volts and will remain at −30 volts during the fixed period after time T _3. will be. The voltages present at the anodes of diodes 69 and 71 are the superposition of the alternating current flowing through winding 29b and the voltage shown at -30 volts. After time T ₃ , the peak positive stroke of voltage 101 is less than +22 volts of voltage 102, as shown in FIG. 3, thus reverse biasing diodes 69 and 71 and during all periods of the fixed period. Decoupling the AC potential from the horizontal deflection circuit through winding 29b. The starting power supply capability of transformer 29 is reduced by a combined secondary winding 29b to -30 volts terminal 56 so that the voltage present at terminal 56 is zero, and all of the peak positive stroke of the ac potential is diode 69 and It can be applied through 71 and is not degraded by any negative DC voltage.

Claims (1)

As shown in the figures and described in the text, the primary stop responds to the pulsating primary alternating current power supply, and the primary stop within the inrush current flowing during the initial period and for primary primary voltage supply. Filter device connected to the device, the load circuit, the secondary stop for generating the primary operating voltage for the load circuit during the initial period and the load circuit for replacing the primary operating voltage during the fixed period and the secondary operating voltage. A starting power supply for a television receiver comprising a device connected to the load circuit for supply, comprising: a primary winding 29a connected to the filter device 28 where the inrush current flows, and a secondary alternating current during the initial period. Apparatus 29b for coupling the device 29b in response to the inrush current for increasing the potential and connected to the primary winding 29a and the tertiary voltage (-30V) to the secondary rectifiers 69, 71. )Wow And the tertiary voltage changing the value from the initial period to the fixed period in the same manner as the decoupling supply method of the secondary alternating current from the load circuit during all periods of the fixed period. An inrush current starter circuit for a television receiver containing a start decoupling circuit.

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