DE1462938C3 - Deflection circuit for television receivers - Google Patents

Description

charged during the retraction interval by the discharge current of the energy storage capacitor and the other, low-voltage power consumers of the receiver are connected in parallel.

This circuit has the advantage that there is no intolerable influence on the linearity of the trace interval of the sawtooth occurs because the charge reversal of the energy storage capacitor occurs in a resonance process takes place, the excitation amplitude of which has only a relatively small effect on the resonance oscillation has, so that differences in charge of the capacitor provided according to the invention have the initial linearity do not influence impermissibly. Also, this capacitor is only used during the retrace intervals charged, during the trace intervals, however, by the energy storage capacitor switched off because the controlled silicon rectifier is blocked during these intervals. The inventive The circuit can, for example, use a DC supply voltage of 140 V for the deflection circuit design, the low voltage removed from the capacitor z. B. can be 20 V.

Further refinements of the invention emerge from the subclaims. An embodiment the invention is explained in more detail with reference to the drawings. It shows

F i g. 1 is a circuit diagram of a television receiver incorporating an embodiment of the invention, and

F i g. FIG. 2 is a graphical representation of a number of signal waveforms to which the explanation of FIG Operation of the in F i g. 1 reference is made to the circuit shown: the waveforms are not shown to scale.

F i g. 1 shows an embodiment of the invention in connection with a typical television receiver, which is connected to an antenna 10, and a receiving part 11 with demodulator, video amplifier, which is connected to a cathode 13 of a picture tube 12, including a sync pulse separator 14, a vertical oscillator 15, a vertical output stage 16, the output terminals YY of which are connected to a vertical deflection winding 17, a phase detector 18 and a horizontal or line oscillator 19 contains. The output signal of the line oscillator 19 is a control electrode 21 of a controlled semiconductor rectifier, for. B. a controlled silicon rectifier 22, which also has an anode 23 and a cathode 24. The anode 23 is connected to a coil 25 with a relatively small inductance. A circuit arrangement 26 for generating a relatively low DC voltage is connected between the cathode 24 of the rectifier and a reference voltage point such as ground and thus in series with the rectifier 22. The circuit arrangement 26 contains an energy storage capacitor 26 a, to which a resistor 26 b is connected in parallel, which represents a consumer for the voltage source formed by the circuit arrangement 26 and can consist of other parts of the receiver. A second energy storage capacitor 27 is connected between the end of the coil 25 facing away from the anode 23 and ground. A third energy storage capacitor 28 is connected with its one terminal to the connection point between the coil 25 and the capacitor 27 and with its other terminal to the series connection of a blocking capacitor 29 and a line deflection winding 30. The combination of the capacitor 29 and the winding 30 is also connected in parallel with a diode 31 and a source 32 for a relatively high voltage. In the circuit with the series connection of the diode 31 and the voltage source 32, a coil 33 of a relatively high inductance is also connected in order to form a direct current path for the diode 31. In a corresponding manner, a coil 34 of relatively large inductance is connected between the connection point of the diode 31 with the voltage source 32 and the connection point of the capacitors 27 and 28 in order to form a charging circuit from the source 32 to the capacitors 27, 28. A pulse suppression circuit consisting of a capacitor 35 and a resistor 36 is connected between the anode 23 and the cathode 24 of the rectifier 22.

The line oscillator 19 delivers positive pulses during operation, for example a width of 5 to 10 microseconds and have a repetition frequency of 15,750 Hz. These positive impulses become the Control electrode 21 of the controlled silicon equalization

s5 judge 22 fed. The rectifier 22 conducts the return part of the line deflection cycle whenever a line pulse is applied to its control electrode becomes, as will be explained later.

In Fig. 2 is the course of currents and voltages, which at different points of the in F i g. 1 occur for two complete deflection cycles. shown. The deflection or forward part of the first deflection cycle occupies the time interval ί ₀ to f ₂ and the return part of this cycle takes the time interval ί ₂ to ί ₄ . Typically, the time interval ₀ to ί is about 53 microseconds and the interval t to i _{4 is} about 10.5 microseconds.

With the in F i g. The curves shown in FIG. 2 correspond to the signs of the voltages and the direction of the currents corresponds to the polarity indications that are used for the corresponding circuit components in FIG. 1 are shown. The positive current direction corresponds to a current flow from one positive to one negative terminal of the circuit element concerned.

In Fig. 2 means:

Curve A = current / _i30 in deflection coil 30;

Curve B = control electrode current / ₂₁ of rectifier 22;

Curve D = current Iscr 22 ⁱⁿ rectifier 22;
Curve E = current / ₃₁ in diode 31;
Curve F = current / _c , ₇ in capacitor 27;
Curve G = current / _C28 in capacitor 28;

Curve H = voltage V _{L 30} across deflection coils 30;

Curve / = voltage V _sc % ₂₂ at rectifier 22; Curve K = voltage F ₃₁ across diode 31;

Curve M = voltage V _{c 27} voltage across capacitor 27;

Curve N = voltage F _{c 28} voltage across capacitor 28.

During the deflection portion of each cycle, diode 31 holds the combination of capacitor 29 and the deflection winding 30 on the practically con

constant DC voltage that the voltage source 32 supplies. The curve A in FIG. 2 shows that the current flowing through winding 30 in the deflecting part (i ₀ to t ₂ ) is practically linear. As the drawing shows, the current flows through the deflection winding 30 at the beginning of the deflection interval in a first direction and decreases linearly, then goes through zero and finally increases again linearly in the opposite direction. According to the sign agreement made here, the current flowing through the winding 30 is negative at the beginning of the deflection and positive at the end of the deflection.

During the _{retrace interval (f 2} to i ₄ ), the current in the deflection winding returns in the course of an approximately sinusoidal half-oscillation to the value it had at the beginning of the preceding deflection interval. In the ideal case, the negative and positive peak values of the current flowing through the winding 30 are practically the same and their magnitude corresponds to the magnetic field strength which is required to deflect the electron beam in the tube 12 over the fluorescent screen.

The curve of the deflection current shown is generated as follows:

Immediately before the initiation of the return portion of the deflection cycle, i.e. immediately before t ₂ , the diode 31 is biased in the forward direction, and an essentially constant voltage is applied to the deflection winding 30 from the voltage source 32 (see curve H during the line interval). At time r ₂ , the control electrode 21 of the controlled silicon rectifier 22 is supplied with a positive current pulse (curve B) which coincides in time with the horizontal synchronizing pulse of the oscillator 19. The rectifier 22 ignites and thereby causes the capacitor 27 to discharge in an approximately sinusoidal manner through the circuit of relatively low time constant which contains the coil 25, the rectifier 22 and the circuit arrangement 26. The rapid voltage drop across capacitor 27 is coupled to diode 31 through capacitor 28. The diode 31 is thereby biased in the reverse direction, blocks and switches off the voltage from the deflection winding 30. The discharge of the capacitor 27 and the resulting blocking of the diode 31 produces a disturbance in the resonance circuit containing the capacitors 27, 28, the coils 25, 33 and the winding 30. The voltage on the winding 30 and the current flowing through it thus run according to part of an essentially sinusoidal oscillation (see curves A and H). The period of oscillation of the last-mentioned circle is set to, for example, twice the return period.

At the time f ₄ , the charges on the capacitors 27, 28 have assumed such values that the algebraic sum of the voltages on these capacitors and thus the voltage on the winding 30 has such a sign and such an amount that the diode 31 is again in the forward direction is biased. The current through the winding 30, under the influence of the essentially constant voltage which is supplied by the voltage source 32 and the diode 31, again assumes the linear course corresponding to the line deflection. During the first part of the line interval, part of the deflection coil current flows through the forward-biased diode 31 and supplies energy back to the voltage source 32. A second component of the deflection current supplies energy to the capacitor 28 and the circuit arrangement 26, which operates as a low-voltage source, via the coil 25 and the controlled silicon rectifier 22. This last-mentioned component of the deflection current reduces the current flowing from the deflection winding 30 through the diode 31 (see curves E and G between, for example, times / ₄ and t _s ).

During the interval r ₄ to t _s and in the rest of the line deflection part of the deflection cycle, the energy transferred to the capacitors 26 a, 27, 28 has practically no effect on the desired linear deflection current in the winding 30, since the diode 31 remains conductive and the desired constant Maintains tension on winding 30 throughout the deflection.

As curve D shows, the controlled silicon rectifier 22 conducts in the flow direction at the end of the return, and in practice it also conducts during part of the line deflection, namely from time t _i to time Z ₅ or from time Z ₀ to time t _v while the portion of the deflection current supplied to the capacitor 28 approaches zero. The period of oscillation of a first circuit containing the coil 25, the capacitor 28 and the winding 30 and of a second circuit containing the coil 25 and the capacitor 27 are dimensioned with respect to the return period so that the sum of the currents from the capacitors 27, 28 passing through the rectifier 22 flow into the circuit 26, is positive at the end of the return. The coil 34, because of its relatively large inductance, can be neglected in the following consideration of the operation of the circuit during the line or deflection portion of the deflection interval.

If both the diode 31 and the rectifier 22 conduct in the forward direction, the capacitors 27, 28 are practically connected in parallel to each other, and this parallel connection is parallel to the series connection of the circuit arrangement 26 operating as a low voltage source, the controlled rectifier 22 and the coil 25. The The period of oscillation of the resonant circuit, which contains the parallel connection of the capacitors 27, 28 in series with the coil 25, determines the duration of the leaning of the rectifier 22 during the line deflection part of the deflection cycle. The last-mentioned resonance circuit blocks the flow of current through the rectifier 22 in the following way: At time r ₀ when the diode 31 is switched on, a sinusoidal oscillation begins in the circuit containing the coil 25, the capacitors 27, 28 and the rectifier 22 (see the Curve D, which indicates the course of the current flowing through the rectifier 22). It should be noted that the current flowing through the rectifier 22 consists of the sum of the currents from the capacitors 27, 28 during the beginning of the line interval. As curve D shows, the current through rectifier 22 initially increases at the beginning of the line interval, then drops sharply and goes through zero. The current then begins to increase somewhat in a negative direction. The current flowing through the rectifier 22 in the negative direction, that is to say from the cathode to the anode, however, causes the rectifier 22 to block. Due to the rapid switching of the rectifier 22, in the resonant circuit from the inductances of the switching

7 8

tung, ζ. B. the coil 25, and the relatively small elec- capacitors 27, 28 in relation to each other and on electrode capacity of the rectifier 22 oscillations the other circuit parameters are dimensioned to be triggered (see the pulse at time f _x that the sum of these Capacitors resulin the oscillation /). These oscillations are tending to keep the diode 31 conductive during the line interval through the resistor 36 and the capacitor 35 and damped during the reset, so that the interval running through the rectifier 22 drops sufficiently so that the negative current flowing through the diode 31 exponentially approaches zero goes can be locked. These circuit components and the rectifier then flow a current are preferably also dimensioned so that the impedance is very high. controlled silicon rectifiers 22 during a

After blocking the controlled rectifier io part of the line deflection of the deflection cycle in flux

22, the capacitors 27, 28 are kept conductive across the coil direction, because then a DC

33, 34 of which the relatively high voltage from converter 22 with a relatively small permissible

for example +140 volts supplying voltage source 32 sigen peak current can be used because

charged. the charging current flow is distributed over a period of time that

From curve D (Fig. 2) it can be seen that 15 is greater than the return duration. The capacitor 29 the controlled rectifier 22 during the reverse is dimensioned, if desired, so that the deflection interval and part of the line interval current receives an S-shaped profile, a substantially rectified current flows. The in F i g. The circuit shown in Figure 1 was built under This current comes mainly from the charge, the use of the following components and which operated successfully in the capacitors 27, 28 during the steering part of the cycle. The ones in the
Capacitors 27, 28 stored energy is used for controlled silicon

Part of the deflection winding 30 and part of the rectifier 22 G. E. Type C 40 D.

Voltage source operating circuit 26 is supplied. 'Coil 25 210 μΗ

The parallel connection of the resistor 26 & and 25 capacitor 26 a 10 uF

the capacitor 26 α converts the rectifier capacitor 27 0 22 uF

22 delivered unipolar impulses into an essentially '

lent constant voltage around that as B + voltage capacitor 28 0.68 _μ Ρ

via a line 26 c other stages of the emp capacitor 29 8 μΡ

fangers, ζ. B. the line oscillator 19, the vertical 30 DC voltage source 32 ... 140 volts

oscillator 15 etc. supplied or as a heating voltage horizontal deflection winding 30 750 μΗ

for the picture tube 12 can serve. The shown diode31 type IN2364B

Circuit arrangement works simultaneously as _c '":"' _u

Deflection circuit and a DC-DC converter P ^{b pillars όδ ναύ} ^ ⁴ ^ ⁴¹

(e.g. from 140 to 20 volts). 35 capacitor 35 47OpF

It should be noted that the capacitance of the resistor 36 is 1000 ohms

For this purpose 2 sheets of drawings

Claims (3)

1 2 There has also already been a deflection circuit for television receivers has been proposed in which the deflection winding via a diode with a voltage 1. Deflection circuit for television receivers, connected to the source and the voltage source a which the horizontal deflection winding via a 5 series connection of a capacitor and a conductive diode is parallel to inductance during the trace interval. The capacitor is one a DC voltage source and parallel series connection of a second inductor and for the deflection winding an energy storage condenser - a halter controlled by synchronizing pulses and a discharge circuit for this connected ladder rectifier connected in parallel. The connoisseur, wherein the energy storage capacitor so loading point between the first capacitor and What is measured is that the inductance across him during his discharge is over a second Konladen Occurring voltage drop the diode capacitor with the connected to the diode blocks, and the discharge circuit is connected to the series circuit end of the deflection winding (German processing of a voltage source with a controlled patent specification 12 83 273). Silicon rectifier used during flyback 15 Many of those used in a television receiver Intervals from a sync pulse source in the transistors require an operating voltage of conductive state is controlled, contains and than about 20 to 30 volts. For reasons of economy The resonant circuit is formed, which at the end of it is desirable to have this relatively low DC retrace interval a current reversal in the siliconization in a different way than by means of a network rectifier to block it for the outgoing formator. Interval causes, thereby marked- It is also known in principle that the lines e t that for the simultaneous formation of the deflection circuit to generate an additional Steering circuit as a low voltage source for direct voltage from the line return pulses other power consumers of the receiver to use, with this voltage either the Voltage source (26) in the discharge circuit as an operating voltage available for obtaining a 25 Capacitor (26 a) is formed, which is added during increased DC voltage or as the return interval through the discharge current low voltage to supply other parts of the of the energy storage capacitor (27) charged receiver is used. A well-known scarf is made and the other, with low voltage device, uses additional windings of the to be supplied power consumers (26 ft) of the 3 ° flyback transformer, to which the return receiver are connected in parallel. impulses without galvanic coupling with the rest 2. Deflection circuit according to claim 1, characterized in that windings can be removed so that characterized in that the discharge circuit (22, 25, the reference potential for the low-26 to be generated) also contains an inductance (25). voltage can be chosen freely. This additional 3. Deflection circuit according to claim 2, characterized by 35 borrowed turns increase the cost of the characterized that the connection point of the already expensive flyback transformer. at Inductance (25) with the energy storage capacitor - another known circuit is the Spansator (27) via a second inductance (34) with voltage drop at the capacitively bridged cathode end . Connection point between the diode (31) resisted the line end tube to the power supply and the DC voltage source (32) is connected. 40 of transistors of the audio part of the television receiver used. However, since the current consumption of the audio part is not constant, the effective one changes Cathode resistance of the line end tube, which is particularly disadvantageous during the line trace 45 is the linearity of the sweeping sawtooth. To lessen these harmful effects one must The invention relates to a deflection circuit for the bypass capacitor of the cathode resistor television receiver, in which choose the horizontal stand very high and thus not only higher deflection winding over a cost during the one-way trip, but also a higher space requirement in valls conductive diode at a DC voltage source 5 ° purchase. and parallel to the deflection winding an energy- The object of the invention is to approach Storage capacitor and a discharge circuit for drawing the horizontal deflection circuit to generate these is connected, with the energy storage capacity of a low voltage for other parts of the capacitor being dimensioned so that the voltage drop 55 of the known circuits occurring on it during television reception without the disadvantages of its discharge occurring would,
the diode blocks, and the discharge circuit the series. The task is in a deflection circuit for Circuit of a voltage source with a controlled television receiver, in which the horizontally deflected silicon rectifier, which is controlled during the reverse winding via an interval during the trace interval from a sync pulse source into the conductive diode at a direct voltage source, contains conductive state, and also as ^6o and her an energy storage capacitor resonant circuit is formed, which is parallel at the end of the return and a discharge circuit for this, the running interval causes a current reversal in the silicon equation - a conductive during the return interval, judges to block it for the trace interval controlled silicon rectifier and a voltage. contains source, solved according to the invention in that Deflection circuits for television receivers, the 65 for the simultaneous formation of the deflection circuit a controlled silicon rectifier (thyristor) as a low voltage source for other current behavior, are known (Electronics World, June users of the receiver the voltage source in the 1965, pp. 30 to 32 and 74). Discharge circuit is designed as a capacitor, the