SU257558A1 - - Google Patents

Description

STABILIZED SOURCE

The stabilized high voltage source belongs to the field of radio electronics.

The device is designed to power the second anode of the kinescope in a color television receiver and in various devices, where it is necessary to obtain a high stabilized voltage of about 20-25 kV with a maximum load current of up to 1.5 mA.

The existence of a circuit for obtaining high power supply of alode circuits of kinescopes is characterized by the direct rectification of horizontal scanning pulses, whereby the high-voltage rectifier is energetically connected to the horizontal output scanning stage.

Such a circuit without the use of a special stabilizing device can operate with a beam current of no more than 200; j-a due to the high internal resistance of the source of high voltage. At .maximum current 1 -1 and it can no longer meet the requirement of high voltage constant.

As a stabilizing element, a special lamia device, which shunt the lagruzka, is usually introduced into such a device so that the load on the load remains approximately constant. With low HIGH VOLTAGE

The loads of almost all high-voltage source power are dispersed on this lamp.

Such a scheme is not very economical. In a transistor, a special key stage is usually used, connected through a step-up transformer with a high-voltage rectifier.

The stabilized gut is made by changing the supply voltage of this converter cascade using a Tpaii3 iCTOpa pass through.

Such a device, albeit more economically, pts with a shunt lamp, but nevertheless does not exclude the inevitable loss of power at the transistor.

Thus, the main disadvantage of the existing high-voltage source circuits is the low efficiency and, therefore, the heavy thermal conditions of the stabilizing element, the need to use a bulky heat sink for the pass-through transistor.

The proposed device is characterized by the fact that an oscillator is included in the collector circuit of the output transistor of the key amplifier; the circuit formed by the secondary winding of the upstream, its transformer, cyA is the nominal capacity of this winding and the input capacitance of the high-voltage rectifier tuned to the harmonics of the non-switching frequency of the pulse-width modulator. This provides an increase in the efficiency and reliability of the device.

FIG. 1 is a block diagram of the stabilized high-voltage source described; in fig. 2 - his prpntsionial scheme.

In the drawings, the following symbols are used: / - key stage; 2 - step-up transformer; 3 - high voltage circuit; 4 - power amplifier and current tok; 5 - latitude; null modulator.

The high voltage is removed from the high-voltage rectifier 3, and a variable voltage is applied to the secondary winding 6 of the step-up transformer 2.

The secondary winding of this transformer together with its capacity and the input capacitor of the rectifier form an oscillating circuit with a frequency of f ,,. The energy noteries in this KOiHType are mainly due to the shunting effect of the load, recalculated: to the secondary winding of the transformer via a high-voltage rectifier.

The nervous winding 7 of the transformer 2 periodically through time T (T - // o) is connected to the voltage source E for the time r (). The energy introduced into the oscillatory circuit will be the greater, the more -.

Therefore, by changing it is possible to compensate for the loss in the casing so that at different loads (within specified limits) the voltage at the output of the high voltage rectifier will be almost constant.

Thus, unlike the known circuits, stabilization is achieved by changing the supply voltage E, and changing over time, which significantly increases the efficiency of the circuit, since it eliminates the regulating element (pass-through transistor), on which most of the power loss is dissipated.

However, as distinguished from the known stabilization schemes, constructed according to the method of pulse-width modulation, in the proposed scheme, not the integrated circuit is used, but tuned to the first harmonic of the horizontal frequency Oscillating circuit, forming P Ы | 1 secondary winding step-up transformer.

The key kocad /, assembled on the transistor 8, operates in an accelerated switching mode along the base circuit. Time control t is reduced to a change in the duration of the saturated state of the transistor 8 by changing the duty ratio of the pulses fed to its input. The duration of these pulses is modulated in the modulator 5. The control voltage is applied to

a pulse modulator with a DC amplifier 4, which compares the high voltage output with a high voltage divider with some reference voltage and amplifies the difference between

they up to the value of the control voltage. The DC amplifier is made on a transistor 9, and the modulator is made of transistors 10 and //. On the modulator 5 nostunyut with the forming circuit impulses special

the forms from which U-shaped impulses of variable duty cycle are formed. Such special-shaped pulses are obtained after the differentiation by an RC-tset of synchronized U-shaped horizontal frequency pulses.

with a duty cycle of about 2 n amplitude iO-20 in, coming from the cascade line scan.

A high-voltage rectifier is used in the stabilizer.

As tests have shown, in addition to economy (efficiency-60%), the circuit has quite good stability (–1%), which practically ensures the normal mode of the second anode of the IB picture tube given the limits of variation of average brightness.

Subject invention

A stabilized high voltage source containing a pulse-width pulser, a measuring organ, a voltage onopiHoro source, a key transistor stage and a high-voltage driver, characterized in that

the efficiency and reliability of the device, the oscillating circuit formed by the secondary winding of the step-up transformer with the total capacity is included in the collector circuit of the output transistor of the key amplifier

This winding and the input capacitance of the high-voltage rectifier tuned to the first harmonic of the switching frequency of the pulse-width modulator.

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