FR2475335A1 - TV CRT line scan oscillation maintenance system - uses controlled switching of line output transformer windings and DC supply to power all TV circuits - Google Patents

Abstract

Sawtooth oscillations are maintained in a horizontal deflection circuit including a deflection coil and a bidirectional transistor switch, controllable by a first winding of the line output transformer. A second winding, closely coupled to the first, is connected to a DC voltage source by an identical transistor switch. The first winding is effectively utilised for line scan only when a third controlled switch, using a diode with relatively short recovery time, is closed. The momentary short-circuit during a forward scan period does not react upon the DC source. Alternatively, the third controlled switch may be only a diode with relatively long recovery time and no parallel transistor. Sound reproduction stages and other circuits of a TV receiver can be supplied with power from the line output transformer. The first winding is disconnected whilst the second winding is connected to the power supply connectors of the end of the recovery time.

Description

The invention relates to a method for maintaining an oscillating electric circuit for the line scanning of a cathode ray tube as well as a horizontal deflection device for such a cathode ray tube, implementing this method. The object of the invention is more particularly to use a single transformer, called a line transformer, not only to maintain the oscillating circuit comprising the line deflector of the cathode ray tube but also to obtain from this same transformer, by means of windings additional, a certain number of supply voltages, stabilized or not, necessary for the operation of the apparatus using said cathode-ray tube, in particular a television receiver
On modern television sets, and in particular color television receivers, peripheral remote control devices often connected to the television are often provided.

This obliges the sector of the apparatus chassis to be carefully isolated so that no peripheral organ is brought to the potential of the sector; which could be dangerous for the user.

Furthermore, attempts have already been made to combine the supply circuits <! U television with the horizontal deflection circuit generating the line scanning on the cathode ray tube.

In this case, the deflection circuit and in particular the line transformer is provided with additional windings providing the different power sources necessary for the operation of the television; the power supply transformer itself being eliminated. This system however has a drawback originating mainly from the fact that a controlled switch is interconnected with the oscillating circuit comprising the line deflector (this oscillating circuit is composed of said deflector constituted by a coil of inductance and two capacitors) to short-circuit one of the components of this oscillating circuit during a forward period of the sweep where the oscillating circuit operates at a low oscillation frequency compared to another oscillation frequency which s' establishes during line return. Indeed, this controlled switch also has the effect of short-circuiting a maintenance winding of the line transformer, which poses problems if another winding of this same transformer is simultaneously connected to a power source. power from the sector One could imagine solving this problem by establishing a relatively loose coupling between the two aforementioned windings of the line transformer, but such a solution seems unsatisfactory due to a low efficiency and above all a level of stray radiation.

important around the line transformer, likely to disturb neighboring electronic circuits and especially the cathode ray tube itself.

 The invention offers a satisfactory solution both to the problem of galvanic isolation between the sector and the various components of the television set and the problem of integrating the power supply function at the level of the horizontal deflection means of this television set.

In this spirit, the invention mainly relates to a method of maintaining an electrical circuit oscillating at two oscillation frequencies switchable sequentially for line scanning of a cathode ray tube, of the type consisting in inducing maintenance energy in a first inductive winding connected to said electrical circuit oscillating at the common point of two capacitors thereof and short-circuiting one of said capacitors periodically, the lowest oscillation frequency being established for a forward period of said sweep-when this capacitor is short-circuited and the highest oscillation frequency being established during a return period of said sweep when this capacitor is not short-circuited, characterized in that it consists, by means a second inductive winding-capable of being connected to a contension voltage source coupled with said first winding with a high electromagnetic coupling factor, by means of a c magnetic circuit
- interconnecting said second winding at the terminals of said zontinueall voltage source during each aforementioned outward period until establishing a predetermined energy level in said magnetic circuit, keeping said first winding disconnected,
- disconnecting said second winding when said energy level is reached by preferably simultaneously connecting said first winding across said capacitor short-circuited until the end of said outward period if said energy level is reached before it ,
- to open the short-circuit across said capacitor during the entire return period by keeping said first winding connected for at least part of said return period, and
- Disconnecting said first winding again, preferably at the end of said return and preferably simultaneously connecting said second winding across said DC voltage source.

Of course, said DC voltage source is simply constituted by a rectifier bridge, for example a diode bridge, connected to the mains, connected to said second winding by means of suitable filtering means. To meet one of the objectives of the invention , this DC voltage source can be galvanically isolated from the rest of the TV chassis
The invention also relates to a device for horizontal deflection of a cathode ray tube and supply, of the type comprising
an oscillating circuit connected to a first inductive winding and comprising the deflector of said cathode-ray tube as well as two capacitors, one of said capacitors being connected between a connection point of said first winding to said oscillating circuit and a point at a reference potential,
a first controlled switch connected to the terminals of this capacitor to short-circuit it during each forward sweep period and put it into service in said oscillating circuit during each return period of said sweep, and
- a second inductive winding coupled to said first winding by a magnetic circuit and connected to a DC voltage source via a second controlled switch
said device being characterized in that the magnetic coupling between the first and the second winding is high and in that it further comprises a third controlled switch, inserted in series with said first winding between said point at a reference potential and said connection point, and control means for controlling said second and third switches controlled in phase opposition.

 To meet one of the aims of the invention, the aforementioned power source, the second inductive winding and the second controlled switch are galvanically isolated from the rest of the chassis of the device.

 Furthermore,: each aforementioned controlled switch is preferably a bi-directional switch controllable in a direction of conduction. In the example which will be described later, a switch of this type is formed by a transistor and a diode connected in reverse between the collector and the emitter of this transistor; the base of the transistor constituting a control input of this switch. We can also consider replacing the transistor with a thyristor or any other suitable semiconductor device. The designation defined above "bi-directio switch, anel controllable in a direction of conduction" simply means that such a switch is likely to lead in both directions if a validation signal is applied to its control input but this switch can spontaneously drive in one of the directions without the need to apply a validation signal to the input of ordered. We will see that the use of such switches greatly simplifies the control circuits of the different switches, by taking advantage of the bis - <e electromagnetism governing the phenomena which follow one another inside the line transformer.

The invention will be better understood and other objects, details and advantages thereof will emerge better in the light of the following description of a currently preferred embodiment of a device according to the invention, given only by way of example and made with reference to the accompanying non-limiting drawings in which
- Figure 1 is a block diagram of a device for feeding and horizontal deflection of a cathode ray tube; and
- Figure 2 is a timing diagram illustrating the operation of the device of Figure 1.

Referring to Figure 1, there is shown in particular a horizontal deflection device 11 of a cathode ray tube not shown and comprising a deflector Ly interconnected with two capacitors Cs and Cr to form an oscillating circuit capable of operating sequentially at two frequencies d 'different oscillation so that the current passing through the deflector Ly is of the "sawtooth type11'More specifically, one of the terminals of the deflector Ly is connected to the chassis ground, that is to say to a potential of reference, and lt-other terminal is connected to a series connection of two capacitors Cs and Cr, one of the terminals of the capacitor Cr also being connected to ground. In addition, a controlled switch I1 is connected in parallel to the capacitor Cr.- The capacitor Cs has a significantly greater capacity than that of the capacitor Cr The switch I1 is of the tbi-directional type controllable in a direction of conduction ", As mentioned previously, this in switch can include a transistor T1 whose 'collector is connected to the common point of the capacitors Cr and Cs and whose emitter is connected to ground (the transistor TI being here of the NPN type) and diune diode D1 connected in reverse between the collector and the emitter of transistor T1, that is to say with its cathode connected to the collector of the transistor. The base of transistor T1 constitutes the corneal input of switch I1 and is connected to a line oscillator L driven by pulses. synchronization applied to the input S of this oscillator A first inductive winding W1 has one of its ends connected to the aforementioned oscillating circuit and more particularly to the point, common of the capacitors Cs and Cr.

The winding W1 is part of the line transformer 12 and is coupled by a magnetic circuit constituted by the core N of this transformer to a second inductive winding W2 connected to a DC voltage source via a second controlled switch I2, identical to the switch I1. More specifically, the DC voltage source is constituted by a rectifier bridge P with four diodes, connected to the sector and by a Resistance-Capacities filter (R1, C1) whose output Eg is connected to one of the ends of the winding W2; the other end of this winding being connected to a ground which is not galvanically isolated from the sector by means of the switch I2. This mass not isolated from the sector is of course rigorously isolated from the mass of the chassis mentioned above. In FIG. 1, - the mass points not isolated from the sector are symbolized by horizontal lines inscribed in a triangle, while the points of the chassis mass are symbolized by oblique lines inscribed in a rectangle, The base of the transistor
T2 of the switch I2 which constitutes the control input of this switch is therefore connected to a winding of an isolation transformer Ti, the other winding of which receives the control signals produced by a regulation unit
R, known per se, which unit receives its error voltage from an auxiliary winding W7 wound on the core N. The line oscillator L is also connected to an input of the regulation unit R to synchronize its operation .

According to the invention, the coupling between the windings
W1 and W2 are high In practice, it is possible to consider winding these two windings on the same "leg" of the transformer 12. Furthermore, in a preferred embodiment of the invention, all the windings of the transformer 12, including those which will be described later, are wound on the same "leg" of the line transformer, which has substantially the shape of a ferrite frame with a large window, according to a usual embodiment of a line transformer.

According to another important characteristic of the invention, the device of FIG. 1 further comprises a third control switch I3 inserted in series with the winding W1 between the ground and the connection point of the winding W1 and the oscillating circuit De preferably, the switch I3 is inserted as shown in FIG. 1 between the terminal of the winding W1 which is not connected to the oscillating circuit and the ground of the chassis of the television set.

If nn considers the transistor T3 of the switch I3) its collector is therefore connected to the winding W1 and its emitter is connected to ground. Diode D3 is connected between the collector and the emitter of transistor T3. The base of the transistor T3 which constitutes the control input of the switch 13 is connected to an additional winding W3, (via a series connection of a resistor
R3 and a capacitor C3) wound on the core N and the other end of which is connected to ground. Of course, according to what has just been said previously, the coupling between the winding W1 and the winding W3 is high.

Finally, we note that, in a classic way, the source
THT consists of several W6 windings wound on the N core and interconnected in series by means of D6 diodes. As will be seen below, these elements supply the high voltage of the cathode ray tube (THT) by rectification during line return L-one of windings W6 is connected to ground by an omnDdon en pwnllele of a resistor and a capacitor (R3, C3) making it possible to take at output 15 a signal representative of the current supplied by the THT source.

Another winding W4 at one of its ends connected to a diode D4 to provide a stabilized voltage B + filtered by a capacitor C4 + As will be seen below, this voltage is stabilized because the winding W4 only flows during periods of line return; the peak voltage developed at the terminals of the winding W1 (which then behaves as a primary with respect to the winding W4) being stabilized by the regulation unit R. Another winding 5 is also wound on the core N and connected to a diode D5 which charges a filtering capacitor C5 to supply an unstabilized voltage Vson intended to supply the LF stages of the television. As will be seen below, this voltage is not stabilized (eiF will not need the input) because winding W5 only outputs during the forward periods of the sweep.

It will be noted in this connection that the direction of the windings of the transformer 12 is not indifferent, the analogous terminals of each winding being traditionally identified by a point, on the diagram in FIG. 1. Thus, it will be noted that the windings W1 , W3, W4, W6 and W7 are all wound in reverse of the windings W2 and W5. Of course, an inversion of the winding direction of one of the windings accompanied by an inversion of the connections to its terminals does not change anything. It is simply apparent from FIG. 1 and from the directions of the windings as shown in this figure that , if a positive voltage, for example is generated at the terminals of the winding W1 acting as a primary, a voltage of the same polarity will be generated at the terminals -of the windings W3, W4 W6 and W7, but that on the other hand, a negative voltage will be generated, for example, at the terminals of the winding W5
We will now describe the operation of the device which has just been described, referring to the timing diagram of FIG. 2. On this timing diagram,:
FIG. 2a represents the current Ip in the winding W2,
FIG. 2b represents the voltage V (I2) at the terminals of the switch I2;,
- Figure 2c shows the voltage V (I3) across the switch I3 ;;
- Figure 2d shows the current Is in the winding W1
- Figure 2e represents the voltage V (I1) at the terminals of 11 switch Il
FIG. 2f represents the current I (I1) passing through the switch li, and
FIG. 2g represents the basic current I (L) of the transistor T1, that is to say the control signal applied by the oscillator L to the control input of the switch Iî
Furthermore, the different characteristic instants of the operation of the device in FIG. 1 are marked on the abscissa. As the timing diagram of FIG. 2 represents substantially two complete cycles of operation of the device, a characteristic instant can be indifferently analyzed at times ti or t ' it We will first of all consider the operation of the line deflector Ly in conjunction with the capacitors Cs and
Cr with which it can define two oscillating circuits with different oscillation frequencies depending on the state of the switch I1. The capacitor Cs has a capacity significantly greater than that of the capacitor Cr but the switch Iî is connected in parallel to the capacitor
Cr, so that the capacitor Cs is the one which defines with the inductance of the deflector Ly the oscillation frequency during a forward period of the sweep while the oscillation frequency during the return (higher) is defined by the values of the inductance of the deflector Ly and of the capacitance of the capacitor Cr During the sweeping phase where the capacitor Cr is short-circuited, the transistor T1 can be triggered at a non-critical instant, subsequent to the start of the scanning because the direction of the current in the deflector Ly is such that the oscillating circuit Ly, Cs is closed by the diode D1 which conducts substantially during the first half of the forward scan, as long as the current is "negati'f" considering the curve f, that is ie until now ta ;; The transistor Tj is preronded before this instant (in tb) by the rising edge of the pulse delivered by the line oscillator L (curve g) so that at automatic blocking of the diode D1, when the current changes direction in the deflector Ly at the instant ta, the oscillating circuit Ly, Cs can continue to oscillate because T1 is saturated and this until t2 (or t'2), this instant being marked by the falling edge of the delivered signal by 1 Line L oscillator which initializes the return of the sweep.

At this instant, t2 the trans-istor T1 crashes. At this time, the oscillating circuit changes characteristic frequency since it is now essentially constituted by the deflector Ly and the capacitor Cr Of course, this capacitor Cr is discharged at the start of the sweep return. However, the current in the deflector Ly is important so that this inductance will discharge in the capacitor and the current in Ly will decrease progressively (Ly "charging" Cr) developing at the terminals of the capacitor
Cr a "positive" voltage, that is to say blocking the diode D1 the energy of the induction of the deflector Ly thus being able to be transferred only in the capacitor Cr since the switch 51 is open. . In this way, the current in the Ly deflector will gradually decrease until it is canceled out in the middle of the line feed. At this precise instant (the middle of the line return), the energy is therefore maximum in the capacitor Cr, which will begin to discharge in the deflector Ly by causing a current of opposite direction to flow therein, until the end of the line return.

 At this time (instant t3 or t'3), the energy is again maximum in the deflector Ly but the current is' reversed. This fulfills the conditions for the automatic stop of the line return sweep because, when the deflector Ly will start its discharge process again, this can only be done by charging the capacitor Cr with a negative capacity which leads to conduction. diode D1-, that is to say the automatic closing of the switch Il From this moment, the operating conditions and in particular the oscillation frequency.

of the line scanning circuit change again since the capacitor Cr is again short-circuited. A new go cycle is immediately started with an oscillating circuit (Ly Cs). It will be noted that, at the end of the line return, (instant t3 t-3)., The transistor T1 has no need to be saturated since the short-circuiting of the capacitor Cr is carried out automatically by the conduction of the diode D1 '* The conduction of the transistor T1 will intervene only later, -. at the time of the rising edge dw signal from the line oscillator L, so that the transistor T1 is ready to drive at the moment (ta) when the -current in -the switch I1 will change direction (curve f) is that is to say when the diode D1 can no longer ensure conduction,
On the other hand, it will be noted that the winding W1 1 is in fact connected, during line return, to the terminals of an energy source which is constituted by the oscillating circuit (Ly, Cr) the capacitor Cr developing a positive voltage across 11 winding-W1, since switch 13 is closed, other end of this winding W1 beingannsi.

More precisely, during the first part u line return, the switch I3 will be closed by the conduction of the diode D3 at t1 and then, at the change of sign of the current Is in the winding W1, by the saturated transistor Te, which will have been put into a preconduction state from the start of the line return thanks to the winding W3 applying at its base a positive voltage pulse of the same shape as that which develops at the terminals of the open switch I1 ( curve e) since the winding
W1 behaves at this time as a "primary" for winding W
3.

 At the end of line feed, the base of transistor T3 is no longer supplied (V (W3) = O) and therefore transistor T1 is blocked at time t3 (curve d) and all the voltages across the various windings suddenly reverse. Consequently, the diode D2 is in a state of instantaneous conauire, which results in the immediate appearance of a current in the winding W2 (aiirte a, instant t3).

This point deserves to be emphasized because it is noted, by comparing the curves d and a, that the system is designed so that the switches I2 and 13 operate naturally in phase opposition; the change of state of the switch 13 at time t3 causing the change of state of the switch 12 by the simple effect of the laws of electromagnetism which want that, when one cuts a current circulating in a coil, a reverse voltage immediately appears at its terminals Consequently, the sudden cut of a notable current Is in the winding W2 W2 (curve d) at the end of the line return (t3) is instantly compensated by the appearance of a current Ip in I1 winding W2. There is therefore conservation of the ampere-turns in the magnetic circuit constituted by the core N which, otherwise (that is to say if the current Ip could not circulate in winding W2 by not simultaneously opening the switch I2) would dissipate in the form of heat and generating overvoltages in the other winding W4, W5, W6 etc.

In other words, the fact that a winding (W2) is precisely in a state of driving at the precise moment when an other winding (W1) is disconnected, ensures the transfer to the winding W2 of all the energy stored in the winding W1 and consequently prevents this anergy from being distributed in particular in the other windings by creating harmful overvoltages in these
From the instant t3, the winding W1 therefore plays its role of primary but the current (hegative "considering the curve a) which suddenly becomes established in this winding when the diode D2 is turned on is of sense contrary to that which tends to be imposed by the continuous voltage source E connected to the other terminal of this winding. Consequently, during a certain time interval (t3 - t4), the current in the winding W2 will decrease in absolute value until canceled and will remain zero until the transistor closes
T2 whose command is generated by. the regulation unit
R, the operation of which will be analyzed more clearly. From the instant t4 to the transition of the transistor t2 (instant t'0), the transformer is fully relaxed and the voltages across the windings W1, W2 are zero. This time interval is more or less long and depends on the control signals generated by the regulating unit RA the closing command of the transistor T2, the current-imposed by the source E will increase during the whole interval of time t'0- t 'where the regulating means will maintain the transistor T2 .. in conduction Lt-energy stored during this time in the winding W2 therefore depends only on the source voltage E and on the time interval t10- ttl which may vary under the action of the regulation, in particular to compensate for possible variations in the mains voltage.

At the opening of the transistor T2, the current is suddenly cut off in the winding W2 and the conditions are again fulfilled for simultaneous switching and in phase opposition of the switches I2 and I3. In fact, when the current is suddenly cut off in the winding W2 (curve a, instant t'1) the voltages across the winding W1 and the other windings are suddenly reversed, which instantly puts the diode D3 in conduction state (in other words, the switch I3 closes automatically) and as this occurs during a sweeping period, -the switch I1 is closed, so that a current can instantly cross the winding ~:: Wl whose terminals are short-circuited For the same reasons as above, any dissipation or overvoltage is avoided in the system by the fact that a winding (W1) is put into driving condition at the precise moment when the current is cut in another winding (W2). Another important characteristic of the invention also appears clearly at this stage of the description of the operation, namely that the winding W1 is never short-circuited (switches I3 and I1 closed at the same time) when the winding W2 is actually connected to the power source E (I2 closed which allows very good coupling between the windings W1 and W2 (as mentioned previously, the windings W1 and W2 can advantageously be wound on the same core leg or magnetic circuit of the transformer line) and therefore, we are assured of a very weak radiation from the line transformer which does not risk disturbing the operation of the other elements of the television and in particular the cathode ray tube, very sensitive to parasitic fields * During the time interval -t ' 1 - t'2- whose duration can be made variable by the regulation unit
R - the winding W1 has regained its role of "primary" but does not perform other functions than to conserve the energy in the core N of the line transformer at the level where it has been provisionally stored during the time interval you
After which, the falling edge of the pulse generated by the line oscillator L controls the opening of the switch I1 at 11 time t92 and a new line return cycle is initialized, according to the process previously described.

We will now describe the role of the regulation unit R which can be obtained by any servo system, known per se, capable of varying the instants' t0 and / or t1, at each cycle! The main purpose of this regulation is to stabilize the current in the deflector Ly and it has already been indicated above that the invention also makes it possible to obtain stabilized voltages as well for supplying the high voltage (THT) necessary for the operation of the cathode ray tube, as to supply the various electronic circuits of the television set (W4, Di) For this, we could choose to directly stabilize the current flowing through the deflector
Ly by means of a servo control However, it is preferred to take as a setting value the peak voltage across the capacitor Cr during the line return, that is to say when the switch li is open, nui.soue this voltage is proportional to the current flowing through the deflector Ly. However, as this voltage which is also that which is observed at the terminals of the winding W1, can be significant (of the order of 500 Volts) we prefer to use a control voltage generated at the terminals of winding W7 (with an appropriate number of turns) as regulating voltage of the regulation unit R since during the line feed, the winding
W1 plays the role of primary for the winding W7 and that the voltage developed then is directly proportional to the current passing through the deflector By.We record no phase shift between the voltage across the winding
W1 and the resulting voltage at the terminals of the winding w7> during the line return, since the coupling between the two windings is high. The regulation system itself will not be described in detail because it is conventional We will however specify as 'example, that the peak voltage across the winding W7 can be transformed into DC voltage used to develop an error voltage by comparison with a reference voltage (given by a Zenner diode) by means of a differential amplifier; the output of this differential amplifier associated with the output of a ramp generator controlled by the oscillator L - command a: udgger of; Schnn The output signal of the Schmitt trigger is of course used for the control of the transistor T2 via the isolation transformer Ti
Another aspect of the operating mode of the device according to the invention relates to the necessary re-injection of energy into the oscillating circuit of the line deflector Ly, to compensate for the losses. This injection occurs automatically during line feed and the difference in intensity, in absolute value, of the current Is between the start (t2) and the end (t3) of the line feed, visible in FIG. 3d represents in particular the losses compensated in the oscillating circuit of the deflector.

 At this stage of the analysis of the operation of the device in FIG. 1, it is possible to clearly identify the fundamental concept of the invention which consists in the use of a single magnetic component in timeshare; this time-sharing use is made possible in particular by the addition of the switch I3 in series with the winding W1.

We will mainly distinguish the following operating phases
- connect the winding W2 (switch I2 closed) to the terminals of a power source (E) for a longer or shorter time during the sweep go to establish a desired energy level in the core of the line transformer, the winding W1 being disconnected so that the latter which then plays the role of secondary with respect to the winding W2 is not in short circuit short during this time, because the switch I1 is closed during the whole sweep period.

- disconnect the winding W2 from the power source (switch 12 open) when this energy level is reached and use the winding W1 to prevent the dissipation of the previously stored energy, in the form of Joule effect, this allowing at a current to be established in winding W1 in short circuit
- Return the W1 winding to the sweeping service during line feed (switch I1 open and switch 13 closed) where its role is essential to maintain the oscillating circuit and possibly use this winding Wt as primary winding, during this period, to supply (in a manner known per se) other windings of the line transformer, in particular to supply different supply voltages for the television set or the cathode ray tubea
Finally, a last important advantage of the invention will be pointed out, namely the possibility of obtaining the supply voltage of the sound reproduction stages of the television, from the line transformer. In fact, these stages operate in class B and therefore require large current peaks. However, with the device shown in Figure 1 we see that the winding W5 is wound in "opposite direction" from the other windings such as W4 and W6, which means that the diode D5 will not be released and will not be able to charge the capacitor C5 only during the forward sweep periods Consequently, the energy necessary for the sound reproduction stages is taken from the line transformer quten outside the return periods of the sweep. The operation in class -B of these reproduction stages does not risk therefore no disturbance of the regulation unit R since the winding 5 is only straight during the sweeping journey where the core of the line transformer is decoupled from the sweeping function proper, due to the timeshare use of this line transformer, which is only possible thanks to the presence of switch I3 at the foot of winding W1; essential feature of the invention.

The fact that the voltage rectified by diode D5 is not stabilized fl.t-is not critical, in the case of; the supply of circuits operating in bu class it is sufficient to provide a capacitor C5 of sufficient capacity to ensure effective filtering Thanks to the invention, it is therefore for the first time possible to supply the sound reproduction stages of a television set from a winding wound on the line transformer As, on the other hand, the ali- mention of the filament of the cathode ray tube from some turns. wrapped around this same magnetic circuit presents no difficulty, so there is, for the first time, the possibility of obtaining all the voltages necessary for the operation of the television from a single magnetic power component, namely the line transformer .

Of course, the invention is in no way limited to the embodiment of the device which has just been described.

In particular, the windings W1 and W2 are shown in FIG. 1 as being galvanically independent. This is of course the condition of galvanic isolation of the chassis of the television set from the mains. However, if it is considered that this galvanic isolation is not essential, it is possible to combine the winding of the windings W1 and W2 into a structure d 'auto-transformatetir. Ultimately, if one seeks to further simplify the circuit by adopting a transformation ratio equal to 1 between the two windings W1 and
W2, then it is possible to save a winding, the two windings W1 and W2 being combined; That is to say that the invention covers all the technical equivalents of the means involved if these are in the context of the claims which follow.

Claims (3)

 1. Maintenance method of an electric circuit oscillating at two sequentially switchable oscillation frequencies, for line scanning of a cathode-ray tube, of the type consisting in inducing maintenance energy in a first inductive winding connected to said electrical circuit oscillating at the common point of two capacitors thereof and periodically shorting one of said capacitors, the lowest oscillation frequency being established during a forward period of said sweep when this capacitor is short-circuited and the highest oscillation frequency being established during a return period of said scanning when this capacitor is not short-circuited, characterized in that it consists, by means of a second inductive winding capable of being connected to a DC voltage source and coupled to said first winding with a high electromagnetic coupling factor, by means of a magnetic circuit a to interconnect said second winding oulement at the terminals of said voltage source contsue during each aforesaid forward period until apron a predetermined energy level in said magnetic circuit, keeping said winding winding disconnected, to disconnect said second winding when said level energy is reached by preferably connecting said first winding simultaneously to the terminals of said short-circuited capacitor3 until the end of said outward period if said energy level is reached before this. - again disconnecting said first winding preferably at the end of said return and preferably preferably simultaneously connecting said second winding to the terminals of said DC voltage source.  to open the short-circuit across said capacitor during the entire return period by keeping said first winding connected for at least said return period, and 2. Method according to claim 1, characterized in that said first winding is disconnected and that said second winding is simultaneously connected to the terminals of said continuous voltage source at the end of said return period.  7 Device according to claim 5 or 6, characterized in that 'said controlled switch is connected between a terminal of said first winding and a point at said reference potential and that said control means include in particular an additional winding wound on said magnetic circuit, one end is connected to a point at said reference potential, and the other end of which is connected to a control input of said third switch; the coupling between said first winding and said additional winding is preferably high.  6 Device according to claim 5, characterized in that this switch consists of a transistor and a diode connected in reverse between the collector t the emitter of said transistor, the base of the transistor aDSifier ':: a control input of said light switch  5. Device according to claim 4, characterized in that at least one of the aforementioned controlled switches is a bidirectional switch controllable in a direction of conduction4 - a second inductive winding coupled to the first winding and connected to a voltage source connected by means of a second controlled switch, said device. being characterized in that the magnetic coupling between said first and second windings is high and in that it further comprises a third control switch :: inserted in series with said first winding between said point at a reference potential and said point of connection, ale piloting means for piloting said second and third switches controlled in phase opposition  a first controlled switch connected to the terminals of this capacitor to short-circuit it during each forward sweep period and put it into service in said oscillating circuit during each reverse sweep period, and  - an oscillating circuit connected to a first inductive winding and comprising the deflector of said cathode ray tube as well as two capacitors, - one of said capacitors being connected between a connection point of said first winding to said oscillating circuit and - a point at a potential reference, 4 * Device for horizontal deflection of a cathode ray tube and supply, of the type comprising  3 Method according to claim 2, characterized in that said second winding is connected to the terminals of said DC voltage source only during the start of the next outward period until reaching a substantially zero energy level in said magnetic circuit 9. Device according to claim 8, characterized in - that iL further comprises at least one stabilized power supply winding, magnetically coupled to said first winding and associated with a rectifier, the winding direction of this winding and the direction of connection of this rectifier being chosen so that the latter is only active during said period of return to scanning. 8 Device according to one of claims 5 to 7, characterized in that said second controlled switch is controlled by a current regulation system in said deflector at the sweep returns 10, Device according to one of claims 4 to 9, characterized in that it further comprises at least one non-stabilized supply winding, magnetically coupled to said second winding and associated with a rectifier, the direction of winding of this winding and the direction of connection of this rectifier being chosen so that the latter is only active during said one-way period of the sweep.