DE2852942B2 - Image display circuitry - Google Patents

Description

The invention relates to a picture display circuit arrangement having a through which a sägezahnför--shaped current, a part of a well a trace capacitor and a retrace capacitor comprising the resonant circuit forming the coil which is the primary of a transformer, for stabilizing the voltage on the trace capacitor, the

>■> during the run-up time of the sawtooth-shaped current is applied to the primary winding by means of a first diode and by means of a switch connected in parallel to this via a second diode, with a supply /

«Ι DC voltage source via an inductive element a current flows and during the blocking time of the switch as a result of the stored magnetic energy from a winding of the inductive element through a third diode connected to the resonance circuit

i "> current flows, with the current supplied to the switch by the DC voltage source at the same time through the called winding flows and parallel to the DC voltage source, the series connection of the same Line direction switched second and third

in a diode as well as a series circuit, which includes inductive element, and wherein the first diode between the junction of the second and the third diode and the switch is located, according to patent 23 W) 025.

π In the case of such a picture display device, which is called Switched supply voltage circuit can be used on the primary winding of the transformer a substantially sinusoidal oscillation is generated during the blocking time of the switch.

With the vote it is achieved that the tension does not become too high at the Schaller during its blocking time, and at the same time there are vibrations that with stray capacitances and could cause undesired radiation,

v. the. Because the tuning frequency is difficult and only by means of rather expensive elements, e.g. B. transducers, is adjustable. can with a regulation of the line duration of the switch the frequency of it supplied switching impulses cannot be constant. In a

»Hi image display device, e.g. B. a television receiver, can when the horizontal deflection circuit is fed by the switched supply voltage circuit becomes, the difference / wipe between the constant horizontal deflection frequency and the variable one

h ·) Switching frequency to difficulties for the smoothing Output voltage. z. B the high voltage for a picture display tube, the supply voltage circuit to lead.

The invention has for its object to eliminate the need for re-tuning during the Switch blocking time to eliminate sinusoidal oscillation and thus the difficulties for the Avoid smoothing. This object is achieved according to the invention in that the on-run capacitor existing voltage by means of the controlled switch and the first connected to the switch A sawtooth-shaped current with the horizontal frequency flows through the diode to the primary winding that during a first part of its trace time through the first diode and during the other part the delay time, during which the controlled switch is conductive, through a second diode and the switch flows, the second diode is connected in parallel to the series circuit of the switch and the first diode is, whereby through the inductive element, the through the third diode with that through the primary winding, the Tuning and the trace capacitor is connected to the resonance circuit formed by a terminal of the Input voltage resulting current flows during the conduction time of the switch, whereby in the inductive element energy is stored while a during the blocking time of the switch by the inductive element and the third diode flowing current compensates for energy losses.

It should be noted that FIG. 5 of the Offenlegungsschrift of the main patent 23 60 025 shows a circuit which is essentially a combination of a switched Supply voltage circuit and a horizontal deflection circuit, wherein for the two Schalt ^ ngsfunktioncn a common controlled switch is used. There is one Circuit arrangement with a sawtooth-shaped current flowing through it, part of one also one Trace capacitor and a return capacitor containing resonance circuit forming coil, in particular Horizontal deflection coil in a picture display device to stabilize the voltage on the Min-run condenser, which is applied to the coil during the run-out time of the sawtooth-shaped current by means of a first diode and by means of a switch connected in parallel via a second diode, wherein during the closing time of the switch from a supply DC DC voltage source via an inductive one Element a current flows and during the blocking time of the switch as a result of the stored magnetic Energy from one winding of the inductive element connected to the resonant circuit via a third Diode current flows and the current supplied by the DC voltage source to the switch at the same time flows through said winding. So the inductive element is formed at the same time by the winding, so that both that flowing in from the .Speisequelle as that transferred into the sawtooth circuit with the coil Current through the same winding was called and thereby losses due to leakage inductances, as they are with separate Windings occur are avoided. The inductive element is between the supply source and connected to the switch so that the direct current flowing through the inductive element flows through the switch flows and the coil is only traversed by a sawtooth-shaped current. In contrast is in a circuit arrangement according to the invention, the inductive element between the .Speisequelle and the end of the switch facing away from the switch Coil connected. Since this is Lim a Power supply manual, in which the voltage occurring on the inductive element, e.g. B. transformer, is removed and used for the DC voltage supply of further stages, a via the Inductive element supplied direct current does not interfere, on the contrary, this is immediately with the connected DC consumers supplied. Only a part of the needs on the secondary side required energy via storage in the inductive element and transmission during the blocking period of the Switch to be supplied, so that the inductive element can be small.

An embodiment of the invention is shown in the drawings and will be described in more detail below described. It shows

F i g. 1 is a circuit diagram of a circuit arrangement according to the invention,

F i g. 2 waveforms to explain the operation of the circuit arrangement.

The switched supply voltage circuit from FIG. 1 shows a switching arrangement in the form of an npn transistor Tr, the collector of which is connected to one end of the primary winding L of a transformer Γ. The other end of the winding L is connected to one end of a choke L ' , the other end of which is connected to the positive terminal of a DC voltage source Vg, while the emitter of the transistor Tr is connected to the negative terminal of the source Vb . The source Vb is, for example, a rectifier circuit that rectifies the AC voltage of the electrical supply network.

The anode of a diode D2 is connected to the negative terminal, while the cathode of a diode D _{1 is} connected to the positive terminal. The cathode of the diode D ₂ is connected to the anode of the diode D ₁ and the anode of a diode D \ whose cathode is connected to the collector of the transistor Tr . The connection point A between the three diodes is connected to the connection point between the choke L 'and the primary winding L via a flow capacitor G, while a return capacitor C <is arranged parallel to the winding L.

A driver stage Dr for supplying switching pulses is connected to the base of the transistor Tr, the repetition frequency of this stage corresponding to that of the horizontal time base of a television receiver, not shown, of which the feed circuit in FIG. 1 forms a part. Horizontal-frequency signals, which are generated in a known manner, are fed to the stage Dr for this purpose.

During a first part of the horizontal period, the diode D \ is conductive, while the transistor Tr is blocked. A current / flows through the primary winding L and also through the capacitor Ci and the diode D \. If the capacitance of the capacitor G is large enough, it can be said that the voltage V ₍ > across it during the entire horizontal period is at least almost constant, so that the change in the current; which change is shown in FIG. 2a, during the ίο- part h of Hiiilaufzeit when the diode D | is conductive, as can almost be considered the same time, causes the linear // 'therethrough flows into the reactor by a current / energy stored, during which current dtr previous time by this throttle that. this current / 'is maintained. The current /' also flows through the customer sator G and the diode Dj with an almost linear change (decrease), as shown in Fig. 2b. Because the two diodes D \ and D ) are conductive, corresponds to the voltage on

Collector of the blocked transistor Tr almost the value + Vfl with respect to the voltage at the negative terminal of the source, which is the voltage of the circuit, and the voltage at junction A (Fig. 2c) also corresponds to the value + V ₈ .

At a point in time fi, the transistor Tr becomes conductive by a switching pulse which is fed to its base and originates from the driver stage Dr. The current / flows in the same way as it flowed before the instant l \ , but the current / 'now flows through the capacitor Ci, the diode D], the transistor Tr and the source Vs. The two currents -; and + / 'consequently flow through the diode D]. Before the time t] the current / 'decreases, while it increases after the time pulse fi, since it then originates from the source Vb and consequently draws the same energy. The voltage at the collector of the transistor Tr and therefore the voltage at the point A becomes almost zero at the time fi, so that the voltage at the connection point between the inductor Z / and the winding L. which before the time f, was equal to Vb + V ₀ , after this point in time equal to V ₀ . The voltage across the inductor L ' was equal to -V ₀ when in FIG. 1 is seen from the right side to the left side of the throttle and now _{assumes the value Vs - V 0} , which is the slope of the positive edge from FIG. 2b determined.

From the above it should be evident that the circuit arrangement is caused by the current / 'after the time f | Energy is supplied that offsets the losses and stresses that power is applied to. A satisfactory effect is obtained if the current / 'does not become zero during the period, that is to say if the inductance of the choke L' is selected in a certain way. Because the inductance of the winding L is much smaller than that of the reactor L '. becomes the current / zero. This takes place at a point in time f ₂ after the point in time fi, after which point in time the current / its direction reverses and consequently flows through the diode D ₁ in the direction opposite to that of the current / ', the voltages at the choke L' and the winding L remain the same as before time f ₂ , ie Vb-Vo and V _0, respectively.

A short time after the point in time f ₂ and during the trace time at a point in time when the two currents flowing through the diode D] have the same absolute value, the diode D \ does not become conductive. The current / 'now flows through the winding L and the transistor Tr, while the current / through the transistor Tr, the diode Di and the capacitor Q flows. This situation and also that of the voltage considered above remain unchanged as long as the transistor Tr is conductive.

At a certain point in time the base of the transistor Tr is supplied with a negative voltage, as a result of which the transistor Tr blocks at the point in time f3, which point in time is the end of the trace time and the beginning of the flyback time. The two in FIG. Currents shown in Figure 2 continue to flow in the same direction as before, but only decrease in value. The current / 'flows again through the capacitor G and the diode Di, so that the voltage at the connection point A almost returns to the value Ve, while the voltage at the connection point between the inductor L' and the primary winding L assumes the value Vs + Vb Die The voltage at the inductor L ' again corresponds to the value - Vb, and the current /' decreases in an almost linear manner.

After the point in time / 3, the current / flows through the capacitor C ^. This capacitor has been chosen with such a capacitance that it forms a tuned circuit with the winding L and other inductances in parallel, the tuning frequency of which is higher than the horizontal frequency Tr generates and reaches a maximum value, after which it drops. The current / drops to essentially sinusoidal after the point in time ti

κι way off, is zero at the time U during the flyback time, after which it reverses its direction.

Since the capacitance of the capacitor Ci is much higher than that of the capacitor C2, the capacitor C can be viewed as being parallel to the Ditde D]

ι ι which shows that the voltage across this capacitor before time ! 3 is essentially zero. This voltage becomes zero again at the point in time fs at the end of the flyback time after the point in time u , as a result of which the diode D] becomes conductive again. The oscillation stops, the voltage on the capacitor Ci is fed to the winding L , so that the current / flows through the same in an almost linear manner. The time pulse is therefore the beginning of a new period.

The amplitude of the oscillating voltage which is generated on the winding L during the flyback time between the times l · and f ₅ is much higher than the voltage Vs, depending on the ratio of the time between these times to the entire horizontal period during the Tension on the

i (i winding L, which corresponds to the value Vo , does not change significantly during the remaining horizontal period. The amplitude of the flyback oscillation can be kept within the maximum permissible value of the transistor by a suitable choice of the tuning frequencies. Oscillations with essentially the same shape over the horizontal period ar secondary windings of the transformer T are generated Fig. 1 shows two secondary windings L 1 and L ₂ , which are connected to the rectifiers D 1 and D 5, respectively

The DC voltage obtained by the rectifier D ₅ is smoothed by a capacitor C3 and can be used to supply DC power to parts of the television receiver, such as for a horizontal deflection circuit, while the high DC voltage obtained by the rectifier Di. in a known manner the end electrode of a picture display tube, not shown, which also forms part of the receiver. The winding direction of the secondary windings (L], L ₂ and Li) and the line directions of the relevant rectifier can be selected in a known manner, so that a rectifier either during part of the time interval between times Γ3 and h or during part of the remaining time of the Horizontal period is conductive

One of the DC voltages generated on the secondary side of the transformer 7, for example the voltage on the capacitor C3, is fed back to the driver stage Dt , in which a comparison circuit and a pulse duration modulator ensure in a known manner that the conduction time fi to h of the transistor T is changed in such a way that that the voltage at C3 and the other DC voltages remain constant. Such a galvanic separation can be obtained between the primary and secondary windings of the transformer T that one end of the secondary windings is connected to the chassis of the television receiver with direct current, while the primary

Winding is connected to the network with direct current. In such a case the mentioned Feedback path to the driver circuit contain one or more transformers.

Another secondary winding L3 of the transformer ^r> T tors can be used to operate the horizontal Ablenkausgangstransistors Tr 'of the television receiver. A condition here is that the transistor Tr ' is conductive during at least the second half of the horizontal trace time, while it is known that it can also be conductive during part or all of the first half thereof without the deflection circuit being adversely affected thereby, although it is must be blocked during the horizontal retraction time, this time being dependent on the retraction determination of the deflection circuit. The transistor Tr ' is shown in FIG. 1 of the npn type, the base line including a coil L 1 in a known manner. The winding direction of the winding Z.3 has been chosen such that the return oscillation in the drive signal has a negative polarity. Because of the action of the coil Lt, the turn-off of the transistor Tr 'is delayed for a certain time after the point in time h , and as a result, the turn-on takes place after the point in time / 5. The latter must not occur before the ramp-down time has ended.

It will be apparent that a positive polarity for the flyback oscillation could be used to drive transistor Tr ' . But this measure could have the disadvantage that the peak of the oscillation would be cut off by the base current of the transistor Tr'm , so that the negative polarity is preferred.

From Fig. 2a it can be seen that the instant r _{2 at} which the current / passes through the value zero is generally not in the middle of the linear part of the curve shown in this figure. This means that the current / has a direct current component. From Fig. 1 it can be seen that this direct current component is nothing more than that of the current / 'and is therefore dependent on the losses of the circuit arrangement and on the energy to be supplied to the respective secondary circuits. The value can therefore be considerable, which can be considered a disadvantage, since it can cause magnetic saturation of the transformer, although such saturation can be reduced by using a core with an air gap for the transformer T. The direct current component of the current / can, however, be reduced by connecting the right-hand end of the choke L ' to a tap on the winding L , the connection of the capacitors Q and C2 facing away from the diode D' still being connected to the upper end of the winding L is connected.

If the right end of the reactor Z / is connected directly to the collector of the transistor Tr , there will be no direct current component through the winding L at all. In such a case, however, the voltage across the throttle / 'is greater than in the case in FIG. 1 so that the inductance thereof must be higher. It should be evident that the circuit arrangement of the embodiment with this direct connection is the same as that shown in FIG. 5 of DE-OS 23 60 025, with the essential difference that the primary winding L in FIG. 1 is the horizontal deflection coil Ly mentioned patent in a horizontal deflection circuit replaced. As is known, only a small direct current is allowed to flow through a deflection coil for centering purposes, so that F i g. 1 or modified with a tap, as mentioned above, is not suitable for a horizontal deflection circuit. It should also be evident that FIG. 1 is a modification of FIG. 5 of the mentioned OS is with the reorganization of the resonance circuit, so that the Fig. 3, 4 and 6 of the mentioned OS can also be changed in such a way that they are effective as feed circuits instead of deflection circuits.

1 sheet of drawings

Claims (4)

Patent claims: 1. Image reproduction circuit arrangement with a coil, through which a sawtooth-shaped current flows, part of a resonance circuit also containing a trace capacitor and a flyback capacitor, which is the primary winding of a transformer, to stabilize the voltage on the trace capacitor, which during the trace time of the sawtooth-shaped current to the Primary winding is applied by means of a first diode and by means of a switch connected in parallel via a second diode, with a current flowing from a supply / DC voltage source via an inductive element during the closing time of the switch and during the blocking time of the switch due to the stored magnetic Energy flows from a winding of the inductive element via a third diode connected to the resonance circuit, the current supplied to the switch by the DC voltage source flowing at the same time through said winding and parallel to the equation hvoltage source, the series circuit of the second and third diode connected with the same conduction direction and a series circuit which contains the inductive element , and wherein the first diode is between the connection point of the second and the third diode and the switch, according to patent 23 60 025, characterized in that the voltage present at the trace capacitor (Q) is fed to the primary winding (L) of the transformer (T) by means of the controlled switch (Tr) and the first diode (D \) connected to the switch in such a way that the primary winding of a sawtooth-shaped current is flowed through with the horizontal frequency, which during a first part of its trace time through the first diode and during the other part of the trace time, during which the controlled switch is conductive, flows through a second diode (L \) and the switch , which second diode (L \) to Her series connection of the switch "· (Tr) and the first diode in parallel ltet, whereby through the inductive element (L '), which is connected via the third diode (Dj) to the resonance circuit formed by the primary winding, the tuning capacitor and the trace capacitor, a current originating from a terminal of the input voltage (Vn) during the line row of the switch flows, whereby energy is stored in the inductive element (U) , while a current flowing through the inductive element and the third diode (Dj) during the blocking time of the switch (Tr) compensates for energy losses. 2. Image display circuit arrangement according to claim 1, characterized by a further series circuit of aer inductance (L '), the primary winding (L) and the collector-emitter path of a transistor (Tr) which forms the controlled switch which is parallel-connected to the first series circuit The parallel circuit formed is connected to terminals of the input DC voltage source, the first diode (D \) being between the connection point of the second and third diode and the connection point of the transistor u ^ d of the primary winding. 3. Image display device according to claim I. or 2, characterized in that a further secondary winding (Li) of the transformer (T) is coupled to the control electrode of a further switch (Tr ') \ n of the horizontal deflection circuit for switching the same with the horizontal frequency. 4. Image display device according to one of the preceding claims, characterized in that the transformer (T) is electrically isolated between circuit elements which are connected to the primary winding (L) and circuit elements which are connected to the first-mentioned secondary winding (L ₂ ) brings about.