FR2701339A1 - Electrical power supply device cyclically delivering a voltage at the alternate polarities - Google Patents

Abstract

The invention relates to power supply devices for electric elements such as discharge lamps in particular. The power supply device according to the invention includes a voltage source (SC), a control device (4), a switching circuit (3) controlled by the control device for linking an electric element (DL) to the voltage source (SC). In accordance with the invention, the switching circuit (3) is electrically isolated from the control device (4). This allows the electric element (DL) not to be referenced with respect to a potential applied to the control device.

Description

 The present invention relates to a device for supplying, from a DC voltage, an electrical element of the type requiring successive applications of voltages with reverse polarities between two consecutive applications. The invention finds a particularly interesting application in the supply of discharge lamps.

 The supply of an electrical element such as a discharge lamp, from a DC voltage, is commonly carried out using the switching means of an inverter type assembly.

FIG. 1 schematically represents the conventional configuration of an inverter providing such a supply for a DL discharge lamp. Each of the two supply terminals B1, B2 of the lamp DL is connected to a DC voltage source SC, by means of two switching elements I1, I2 and I3, I4, each constituting a switch:
- The first terminal B1 is connected to both the positive potential "+" and the negative potential "-" of the source SC, via a first and a second switch I1, I2 respectively;
- The second terminal B2 is also connected to both the positive potential "+" and the negative potential "", via a third and a fourth switch I3, I4 respectively.

 The switches I1 to I4 are commonly constituted by transistors, for example of the bipolar or field effect type. Their "open" or "closed" state is controlled by a COM control device, to which they are connected by links which in FIG. 1 are symbolized in dotted lines. Conventionally, the COM control device controls the switches I1 to I4 by voltage signals applied with respect to a reference potential, ground for example. The switches thus constitute a bridge, the foot of which is at the reference potential, ie to ground, on the side of the positive polarity "+" in the example shown.

In a first part of an operating cycle, the supply voltage delivered by the source SC is applied to the lamp DL with the positive potential "+" on the first terminal B1, and the negative potential on the second terminal B2. To this end, the first and fourth switches I1, I4 are set to the "closed" state, that is to say "on", and the second and third switches I2, I3 are controlled to be in the "open" state. "ie" blocked ". In a following phase of operation, the first and fourth switches I1, I4 are set to the "open" state, the second and third I2, I3 being set to the "closed" state, so that the positive polarities " + "and negative" - "are applied respectively to the second terminal
B2 and at the first terminal B1.

 This operation is in itself well known.

Among the important problems encountered, there may be mentioned that which consists in avoiding the short-circuiting of the DC source SC, during the switching operations of the transistors or switches I1 to I4. I1 is known for this purpose to arrange dead times during switching, using monostable circuits (not shown). This has the consequence of increasing the complexity of the device, its size and its cost, without however constituting absolute security, because in certain cases of an environment very electromagnetically polluted, it is difficult to avoid parasitic conduction of the transistors which constitute the switching elements I1 to I4.

 It should be noted that particularly polluted environments are found when it comes to supplying discharge lamps, in particular for constituting headlights of motor vehicles.

 The author of the invention has further observed that in certain cases of use of the inverters, there may arise a new significant difficulty, linked to the fact of referencing with respect to a given potential, the mass for example, the foot of the bridge. of the inverter. The author of the invention observed in fact that in certain cases, it was not desirable to carry out this reference as one usually does it, in particular in the case of the uses in which the average value of the electric potential of the load with respect to the mass must be negative. We meet this case for example with the discharge lamps placed in the immediate vicinity of a metallic mass connected to the mass: the cations generated by the ionization of the gas in the lamp are then likely to react with the transparent envelope of the latter, and form opaque compounds which degrade the transparency of the envelope. It is then rather desirable to apply to the lamp a supply voltage in "floating" form, that is to say not referenced with respect to a given potential.

 One of the problems in such a case is that the conventional control devices of the transistors or switches of the bridge, are only intended to operate with signals referenced with respect to the foot of the bridge, and do not generate truly "floating" commands. "for all transistors on the bridge.

 The invention provides a solution to the problems and difficulties mentioned above. It makes it possible to produce a power supply device of small volume, delivering in a simple manner from a possibly continuous voltage, a "floating" voltage intended for the supply of electrical elements whose operation is based on successive inversions of the power polarities.

 The invention therefore relates to a device for supplying an electrical element, comprising, a voltage source delivering a supply voltage, a switching circuit by which the supply voltage is applied to the electrical element, a device control acting on the switching circuit so that the supply voltage is applied to the electrical element cyclically, each cycle comprising at least two consecutive phases in which the supply voltage is applied with inverted polarities, characterized in that the control device is connected to the switching circuit via at least one transformer.

 Such an arrangement makes it possible to obtain electrical insulation, continuously, of the switching circuit with respect to the control device, and consequently allows the voltage source to be at a floating potential.

The invention will be better understood on reading the description which follows, given by way of nonlimiting example with reference to the appended drawings in which:
- Figure 1, already described, illustrates the operation of a known type of inverter;
- Figure 2 is the block diagram of a supply device according to the invention;
- Figures 3a, 3b, 3c, 3d form a timing diagram illustrating the operation of a control device;
- Figures 4a, 4b, 4c illustrate part of the so-called transient operation;
- Figures 5a, 5b, 5c, 5d, 5e illustrate the realization of a dead time;
FIG. 6 represents another version of a control device shown in FIG. 2.

 FIG. 2 shows the diagram of a supply device 2 according to the invention, supplying a supply voltage to an electrical element DL which, in the nonlimiting example described is a discharge lamp. The supply device 2 includes a DC voltage source SC and a switching circuit 3 by which the outputs +, III of the source SC corresponding to the positive "+" and negative "-" polarities of the supply voltage, are connected to terminals B1, B2 of the DL discharge lamp.

 The supply device further comprises a control device 4 used to control the operation of the switching circuit 3.

 According to a characteristic of the invention, the control device 4 is connected to the switching circuit by means of at least one transformer Ta, Tb providing electrical insulation (in direct current) between the control device and the circuit switching 3. The control device 4 can thus operate with voltages referenced relative to a reference potential, ground for example, and control the switching circuit 3 without imposing this reference potential. I1 follows that the switching circuit and therefore all the transistors which they comprise, as well as the voltage source SC and the discharge lamp DL, are at a floating potential.

 In the nonlimiting example described, two transformers Ta, Tb are used between the control device 4 and the switching circuit 3, to control in the latter on the one hand, four switches Q1, Q2, Q3, Q4 constituted by transistors, and to control on the other hand a second series of four transistors T1, T2, T3, T4 of the bipolar type, called in the description "authorization transistors", the function of which is to authorize or prohibit switching by the switches.

 The switches Q1 to Q4 perform a switch function in a manner similar to that of the switches in Figure 1; they can be constituted for example by field effect transistors, for example of the M.O.S. type, or any other type of transistor whose gate or base would be isolated.

The voltage source SC is connected to the discharge lamp DL in a manner similar to that already explained with reference to FIG. 1:
the positive polarity "+ g is connected simultaneously to the drains D of the first and third switches Q1, Q3, the sources S of which are connected respectively to the first and to the second terminals B1,
B2 of the DL discharge lamp;
the negative polarity "-" is connected simultaneously to the sources S of the second and fourth switches Q2, Q4, whose drains D are connected respectively to the first and to the second terminal B1,
B2;
- In addition, the source S of the first switch Q1 is connected to the drain D of the second Q2, and the source S of the third Q3 is connected to the drain D of the fourth Q4.

 The two transformers Ta, Tb each have a primary winding Pa, Pb, and four secondary windings Sla, S2a, S3a, S4a and Slb, S2b, S3b, S4b.

For each transformer Ta, Tb, two secondary windings are used to control in the "on" state two of the switches Q1 to Q4; the other two windings control two authorization transistors T1 to T4 whose actuation prevents the completion of any switching by the other two switches.

For the first Ta transformer
- The first end El of the first secondary winding Sla is connected to the gate G of the first switch Q1, via a diode D1 followed by a resistor R1, the anode of D1 being on the side of the winding. The second end E2 of Sla is connected to the source S of Q1 where are also connected the anode of a zener diode Z1, the emitter of a first authorization transistor T1, a resistor R3 and a capacitor C1, thus that the drain D of Q2 and the second end E2 of the secondary S4b of the second transformer Tb; the capacitor C1 and the resistor R3 are connected by their other end to a common point between the cathode of a diode
D2 and a resistor R2, the other end of which is connected to the base of the first authorization transistor T1. The collector of the latter and the catheter of the zener Z1 are connected to the grid G of Q1. A similar organization is repeated at each of the other switches Q2, Q3, Q4, using the other secondary ones.

- The first end El of the second secondary S2a is connected to the base b of a second authorization transistor T2, by successively through a diode D4 and a resistor R5. At the point common to D4 and R5 are connected a resistor R6 and a capacitor C2 in parallel, the opposite ends of which are joined at a point common to the source S of the second switch Q2, of the emitter of the second transistor T2 and of the anode of a second zener diode
Z2. The catheter of the zener Z2 and the collector of the transistor T2 are connected to the gate G of Q2, where a resistor R4 ends, having its other end joined to the cathode of a diode D3.

- The first end El of S3a is connected via a diode D7 and a resistor R10, to the gate G of the fourth switch Q4 to which are also connected a zener diode Z4 and the collector of the fourth authorization transistor T4. The anode of Z4 is joined with the source S of Q4, the emitter of T4, a resistance and a capacity R12, C4. The base of the transistor
T4 is connected to a resistor R11, the other end of which is connected to the second ends of R12 and
C4 as well as the cathode of a diode D8. The second end of S3a is connected to the source S of Q4.

the first end El of S4a is connected to the base B of the third authorization transistor T3 via a diode D6 followed by a resistor R8, the cathode of the latter being connected to R8 as well as to a capacitor C3 and a resistor R9 in parallel, the other ends of which are connected to the transmitter of T3, to the anode of a zener Z3, and to the source S of the third switch
Q3.

For the second transformer Tb
- the first end El of the first secondary
Slb is connected to the anode of a diode D5 whose cathode is joined to a resistor R7 having its other end connected to the grid of Q3. The other end of Slb is connected to the source S of Q3;
- The first end El of S2b is connected to the anode of D8, in order to control T4. The other end of S2b is connected to the source S of Q4;
- the first end El of S3b is connected to the anode of the diode D3 in order to control the switch
Q2. The other end of S3b is connected to the source S of
Q2.

- the first end of S4b is connected to the anode of diode D2 in order to control the transistor
T1. The other end of S4b is connected to the transmitter of T1 and to the source S of Q1.

 Each of the primary windings Pa, Pb is connected by its first end El to a voltage V1 which, for example, is positive with respect to ground. The other end of each primary is connected to a control transistor TC1, TC2 whose function is to connect or not connect each second end of the primary to ground. These transistors can be, for example, of the field effect type, or of the bipolar type, although the latter have the disadvantage, compared to the field effect, of limiting the operating frequency and therefore of requiring larger transformers Ta, Tb. .In the example shown, the first and second transformers Ta, Tb are controlled respectively by a first and a second control transistors TC1, TC2, of the field effect type, the drain D of which is connected to the primary winding. , the source S to ground, and the gate G of which receives a control signal SC1 for TC1 and SC2 for TC2.

 The control signals SC1, SC2 are voltage signals in the form of slots, having (in a so-called stable or stationary state of operation) complementary "logic" states, that is to say that when the signal SC1 is at "1 ", the signal SC2 is at" 0 "(at this stage of the description, no account is yet taken of a characteristic of the invention according to which the control signals SC1, SC2 are cut up such that they constitute signals" null "or" chopped ", signals which will be further explained in another part of the description); in the example, the state "0" corresponds to a voltage close to ground, and the state "1" corresponds to a positive voltage greater than the conduction threshold of the control transistors TC1, TC2.

These signals SC1, SC2 are delivered respectively by an output 6 and an output 7 of the control device 4.

Under these conditions, when the control signals SC1 are applied to the first control transistor TC1, they cause its conduction which itself generates a current in the primary of Ta and voltages across its secondary. It follows that
- The first and fourth switches Q1, Q4 are set to the "on"state;
- the base of the authorization transistors T2, T3 is supplied (permanently); these transistors are saturated and made conductive, and consequently impose a low impedance between gate and source of the second and third switches Q2 and Q3. This prevents any unwanted and parasitic conduction of these switches Q2, Q3.

 The second transformer Tb not being actuated, these switches Q2, Q3 of course are not controlled, and on the other hand the first and fourth authorization transistors T1, T4 not being activated, they therefore do not short-circuit not the control of switches Ql and Q4.

When the second control signals SC2 are applied in turn
- The first and fourth switches Q1, Q4 are set to the "blocked"state;
- The second and third authorization transistors T2, T3 no longer short-circuit between gate and source of switches Q1, Q3.

It is the turn of the second transformer Tb to be activated
- the switches Q2, Q3 are controlled in conduction and set to the "on" state. The load constituted by the DL discharge lamp then receives a supply voltage having reverse polarities with respect to the previous phase of operation where the switches Q1 and Q3 were in the on state;
- The first and fourth authorization transistors T1, T4 conduct and produce a short circuit between gate and source of switches Q1 and Q4, preventing any undesirable conduction of the latter.

 The frequency at which the polarity reversals of the supply voltage takes place is defined in the control device 4, with the aid of an oscillator or generator of voltage signals 10 delivering first cyclic signals CY1, which successively pass from logic state "0" (voltage close to ground) to state "1" (voltage allowing to put TC1, TC2 in saturation) then to state "0" etc ...

The first cyclic signals CY1 are applied simultaneously to an input el of an "AND" gate P1 with two inputs, to a capacitor C9 and to the input of a first inverter 11. The other side of the capacitor C9 is connected both at the input of a second inverter 12, at a resistor R20, and at the cathode of a diode D20; the other end of R20 and the anode of diode D20 are grounded. The second inverter 12 preferably has hysteresis characteristics in a conventional manner, allowing it to produce a voltage pulse in response to the pulse transmitted to it by C9 during positive variations of the cyclic signal CY1 (the diode D20 eliminating the negative variations) .This niche of voltage is found in positive at output 6 of the door
P1, where it constitutes a signal called "first initialization signal SI1".

 The output of this inverter 12 is applied to the input of a third inverter 13, the output of which is connected to the anode of a diode 21 having its cathode connected to the second input e2 of the gate P1. This second input e2 is further connected to ground by a resistor R21 and to the cathode of a diode D22, the anode of which is connected to a second signal generator 15 delivering second cyclic signals CY2. With the exception of the generators 10, 15, and the first inverter 11, the above-mentioned elements mentioned above form a first logic circuit CL1 which delivers the first control signals SC1 by the output 6 of the gate P1.

The second cyclic signals CY2 carry out the cutting which was previously mentioned. These signals
CY2 go from state "0" to logic state "1" and vice versa. Their frequency is preferably large compared to that of the first cyclic signals CY1. For example, the frequency of the first cyclic signals CY1 can be of the order of 500 Hz and that of the second cyclic signals CY2 can be of the order of 1 MHz; with for each case substantially the same duration of the states "0" and "1".

 The output of the first inverter 11 delivers the first cyclic signals CY1 with a phase opposite to that which is applied to the first logic circuit CL1.

The first inverter 11 applies these inverted signals CY1 to a second logic circuit CL2, constituted at all points in the same way as the first logic circuit CL1.

The second logic circuit CL2 comprises
- a capacity C9 'corresponding to the capacity C9 of CL1;
- A second gate P2 forming an "AND" with two inputs el, e2, and corresponding to the first gate P1;
- resistors R 20 'and R21' which correspond respectively to R 20 and R21 of CL1;
- diodes D20 ', D21', D22 'which correspond respectively to D20, D21, D22 of CL1;
- inverters 12 'and 13' which correspond respectively to inverters 12 and 13 of CL1.

 The circuits CL1, CL2 being identical they operate in the same way, They are actuated from the same cyclic signals CY1, CY2, with the difference however that the first cyclics CY1 are inverted by the inverter 11 to be applied to the second circuit CL2.

When the signals CY1 applied to CL1 are in the state "1", they authorize the passage through the first gate P1 of the second cyclic signals CY2. We then find on the gate G of the first control transistor
TC1, signals which correspond to those delivered by the second generator 15. During this time the output of P2, ie the gate of the second control transistor
TC2 is at "0" because the inverter 11 maintains a level "0" at the input el of the second gate P2.

 When the signals CY1 pass to the state "0", the operation is reversed: the first gate P1 does not let pass the second signals CY2 and the first control signals SC1 maintain the gate of TC1 at "0", the first transformer Ta is not activated. On the other hand, the output of the inverter 11 has changed to state "1" and authorizes the passage of the second cyclic signals CY2 through the second gate P2.

 The second control signals SC2 applied to the gate of the second transistor TC2 are then the image of the second cyclic signals CY2, and the second transformer Tb is actuated at the rate of these second cyclic signals.

 It should be noted that as already mentioned previously, a change of state of the first cyclic signals CY1 from "0" to "1" generates a first initialization signal SI1 at output 6 of the first gate P1, and that due to the action of the first inverter 11, such a signal called "second signal SI2" is generated at output 7 of the second gate P2, in synchronism with each passage from "1" to "0" of these first cyclic signals CY1.

 FIGS. 3a to 3d illustrate the operation described above on a fraction of a cycle of the first cyclic signals CY1.

 FIG. 3a shows that at an instant t0, the first cyclic signal CY1 is already in the state "1" which it keeps until an instant t5 where it goes to the state "0".

Figure 3b shows the second cyclic signal
CY2, and shows that it goes to state "1" at time t0, then to state "0" at time tl, then successively "1", "0", "1", " 0 "," 1 "," 0 "respectively at times t2, t3, t4, t6, t8, t9
FIG. 3c represents the first control signal SC1 and shows that it follows the same changes of state as the second cyclic signal CY2, until time t5 when the first cyclic signal CY1 goes to "0". The instant t5 is that when the control of the first transformer Ta ceases.

Figure 3d shows the second control signal SC2 and shows that it was at "0" as long as the first cyclic signal SC1 was at nl. At time t5 the second cyclic signal SC2 goes to the state "1" qu 'it keeps until an instant t7 where it returns to "0", while the second cyclic signal CY2 has passed from "1" to "0" at an instant t6 which precedes the instant t7. This shows that in the second control signal SC2, the positive slot formed between times t5 and t7 is not generated by the second cyclic signal CY2, but corresponds to the initialization signal SI2 previously cited. Of course a signal of initialization SI1 (not shown) is generated in the first control signals SC1 when the first cyclic signal CY1 goes from state "0" to state "1". These initialization signals SI1, SI2 have a duration T1 fixed by the resistors and capacitors
R20, R20 ', C9, C9' of the control device 4 .. At time t8 the second control signals SC2 go to state "1" which it keeps until time t9 when it returns to "0" and so on. From time t8 the changes of state of the second control signals are in phase with those of the second cyclic signal CY2.

 For each logic state "0" or "1" of the first cyclic signal CY1, the system reaches a steady or stable speed after a few periods of the second cyclic signal CY2.

 FIGS. 4a, 4b illustrate the operation of the switching means 3 in steady state, as a function of the changes of state of the second cyclic signals CY2 shown in FIG. 4c.

FIG. 4a represents variations of a voltage V2 at the gate G of the first switch Q1 (relative to its source S). It should be noted that these variations are also found on the gate of the fourth switch Q4, these two switches Q1 and Q4 being actuated simultaneously:
- assuming that from time t0 the cyclic signal CY2 is in state "1", we see in Figure 4a that the voltage V2 decreases until time tl where the cyclic signal CY2 down to "O" state.

 In fact (with provisional reference to FIG. 2), the voltage V2 results from the current generated by the transformer which restores, at the secondary Sla (between instants tl and t3 illustrated in FIGS. 4a to 4c), 1 "magnetic energy accumulated when the first control transistor TC1 is conductive It should be noted that taking into account the directions of coupling of the windings of the transformers Ta, Tb, when the first control transistor TC1 is conductive, the first diode D1 is blocked.

In the embodiment shown in FIG. 2, the directions of coupling of the windings of the transformers Ta, Tb are adapted to an operation of the “energy return” type well known under the English name “f ly-back”. A "f lyback" is a "DC / DC" converter, that is to say continuous / continuous with energy restitution, the basic diagram of which corresponds substantially for example, to that which is formed in FIG. 2 by l primary winding Pa having one end connected to the positive voltage V1 and the other connected to ground by the switching transistor TC1 forming a switch, which primary Pa is coupled to the first secondary winding Sla, one end of which is connected to the gate
G of Q1 by diode D1, and the other end of which is connected to the source S of Q1 (the gate of Q1 constituting the load of this secondary winding). It should be noted that between the primary Pa and the first secondary Sla the direction of the coupling is "reverse".

The direction of coupling of the various windings is illustrated in FIG. 2 by the fact on the one hand, that at the level of the primary Pa, Pb is carried a point marked 1, and on the other hand that at the level of each of the secondary is worn, either a point marked 1 located on the side of one of the ends and signifying that the direction of coupling relative to the primary is "direct", or a point located on the side of the other end and marked 1 ', and meaning that the direction of coupling is "reverse". For example for the first transformer Ta, the coupling directions are as follows:
- "reverse" for the first secondary winding Sla;
- "direct" for the second secondary winding S2a;
- "reverse" for the third secondary winding S3a;
- "direct" for the fourth secondary winding S4a.

 We find the same arrangement as above for the windings Pb and Slb, S2b, S3b, S4b of the second transformer Tb.

 Thus the voltage delivered by the first secondary winding Sla is applied to the gate G of Q1 (it should be noted that this explanation of operation applies in a similar manner to the cases of Q2, Q3, Q4) via diode D1 and resistor R1, through which the gate-source capacitor (not shown) of Q1 is charged. The value of the voltage delivered by Sal must be sufficient for Q1 to lead to saturation. The maximum value VZ of the voltage V2 is limited by the zener diode Z1.

 Referring again to FIG. 4a, in the time interval between the instants t0 and tl, the discharge of the gate-source capacitor occurs.

The value of the voltage V2 remains, however, greater than that necessary to keep Q1 (and Q4) in saturation. From the instant tl the transformer Ta restoring part of the energy accumulated in the previous phase, the gate-source capacity is recharged until reaching the zener voltage VZ at an instant t2. V2 remains stable until an instant t3 or the cyclic signal CY2 returns to state "1", there is then a decrease in V2 under the same conditions as at instant t0. In fact the grids of Q1 and Q4 are supplied by the transformer
Ta in the way in itself known loads of converters "f ly-back".

 FIG. 4b illustrates the variations of a voltage VC applied to the base b of the second authorization transistor T2 (the second and third authorization transistors T2, T3, being controlled simultaneously, the explanation which follows is also valid for the third transistor and capacitance C3). At time t1, the cyclic signal CY2 being in state 0, the voltage VC decreases until time t3 when CY2 goes to state 1.

With provisional reference to FIG. 2, the voltage VC delivered by the secondary winding Sa2 is applied to the base b of T2 through a diode D4 and a resistor R5; the capacitor C2 is then charged, and the latter discharges into the base of T2 and into a resistor R6 in parallel when the transformer Ta is no longer actuated,
Referring again to FIG. 4b, the time interval between the instants tl and t3 corresponds to the discharge of the capacitor C2. In this operating phase, the minimum of the voltage VC remains greater than a value necessary to obtain the saturation of T2. At time t3 the voltage VC rises with the passage to state "1" of the signal CY2. The value of
VC remains stable until an instant t4 where CY2 returns to the state "0", and where C2 discharges again.

 FIGS. 5a, 5b, 5c, 5d, 5e, illustrate the realization of a dead time between the switching on the one hand of switches Q1, Q4, and on the other hand of switches Q2, Q3.

FIG. 5a represents the second control signals SC2. FIG. 5b represents the voltage VC across the terminals of the capacitors C2, C3. FIG. 5c represents a voltage VC 'applied to the capacitors C1, C4, that is to say to the bases of the first and fourth authorization transistors T1, T4. FIG. 5d represents variations of the voltage V2 'applied between gate and source of the second and third switches Q2, Q3. Figure 5e represents variations of the voltage V2 applied between gate and source of the first and fourth switches Q1, Q4
Assuming that at an instant t0, the first control signals SC1 (not shown) actuate the first transformer Ta, the second control signals SC2 are at "0" (FIG. 5a); the voltage VC on the capacitors is at a value Vst which allows the saturation of the transistors T2, T3 (FIG. 5b); in FIG. 5c, the voltage VC 'is at "0"; the voltage V2 'for controlling the second and third switches Q2, Q3 is at "0"; FIG. 5e shows that the voltage V2 for controlling the switches Q1, Q4 is at 11111.

The instant tl corresponds to the transition from state "1" to state "0" of the first cyclic signal CY1 shown in FIG. 3a, and corresponds to the end of the actuation phase of the first transformer Ta. At this instant tl :
- Figure 5a shows that the second control signal SC2 goes to state "1" (which it keeps until an instant t2 in order to form a slot which constitutes the initialization signal SI2 already shown in figure 3d) ;
- Figure 5b shows that the voltage VC on the capacitors C2, C3 begins to decrease, the secondary
Sa2, Sa3 no longer activated ;;
- Figure 5c shows that the voltage VC 'conduction control in saturation of the first and fourth transistors T1, T4 is applied to the latter;
- Figure 5d shows that the voltage V2 'is still at a value close to zero;
- Figure 5e shows that the voltage V2 applied to the gates of the switches Q1, Q4 is suppressed as a result of the switching on of the authorization transistors T1, T4.

At time t2:
- Figure 5a shows the change to "0" of the second control signal SC2;
- We see in Figure 5b that the voltage VC on the capacitors C2, C3 continues to decrease;
- Figure 5c shows that the voltage VC 'on the capacitors C1, C4 begins to decrease following the change to "0" of SC2;
At time t3; signal SC2 goes to state "l" (FIG. 5a):
- In FIG. 5c, the voltage VC 'having decreased slightly (while remaining largely above the value necessary for the saturation of T1 and T4), it rises to its maximum value;
At time t4, signal SC2 goes to "0" (Figure 5a); the voltage VC on the capacitors C2 and C3, that is to say on the bases of the authorization transistors T2 and
T3, has already reached a so-called blocking value VBL lower than the value necessary to cause the conduction of the transistors T2 and T3;
FIG. 5c shows that the voltage VC '(on C1,
C4) decreases slightly as at time t2); ;
- Figure 5d shows that the voltage V2 'is applied between gate and source of the second and third switches Q2, Q3, with a value VZ suitable for driving these switches in saturated mode.

At this instant t4 the operation arrives at the stabilized operating regime. The time interval between instant tl and instant t4 represents the "dead" time between the switching of switches Q1, Q4 and
Q2, Q3.

 It is thus possible to achieve a dead time in the switching, and in particular to obtain the simultaneity between the appearance of this dead time and the edges of the first cyclic signal CY1. The duration of the dead time is random, with a duration greater than the decrease time of the voltage VC (between the saturation voltage Vst and the blocking value VBL) and less than the preceding duration + T / 2 (T = period of the seconds control signals SC2).

 In many cases, the positioning of the switching edges, with respect to the edges (ie the changes of state) of the first cyclic signal SC1 is of secondary importance. The diagram of the control device 4 shown in Figure 2 can then be simplified.

 FIG. 6 shows the diagram of a device 4a which constitutes a simplified version of the control device 4 of FIG. 2.

 The control device 4a comprises the first and second signal generators 10, 15 already shown in FIG. 2, and which respectively deliver the first and second cyclic signals CY1, CY2. The first cyclic signals CY1 are applied to the input el of an "AND" gate P1 with two inputs, as well as to the input of an inverter 12 whose output is connected to the input el of a second carries "AND" P2. The second cyclic signals CY2 of the second generator 15 are applied simultaneously to the second inputs e2 of each of the two doors P1, P2. The outputs 6 and 7 of the doors P1, P2 respectively deliver signals SC1 'and SC2' which correspond respectively to the first and second control signals SC1 and SC2 previously mentioned, intended to be applied to the gates of the first and second control transistors TC1, TC2.

Claims (16)

 1) Device for supplying an electrical element (DL), comprising, a voltage source (SC) delivering a supply voltage, a switching circuit (3) by which the supply voltage is applied to the electrical element (DL), a control device (4) acting on the switching circuit (3) so that the supply voltage is applied to the electrical element cyclically, each cycle comprising at least two consecutive phases in which the supply voltage is applied with reversed (+), (-) polarities, characterized in that the control device (4) is connected to the switching circuit (3) via at least one transformer (Ta, Tb).  2) Supply device according to claim 1, characterized in that the voltage source (SC) is at a floating potential with respect to the control device (4).  3) Supply device according to claim 1, characterized in that the electric element (DL) is a discharge type lamp.  4) Supply device according to claim 1, characterized in that it comprises at least two transformers (Ta, Tb) by means of which first and second control signals (SC1, SC2) delivered by the device control (4) are applied to the switching circuit (3).  5) Power supply device according to one of the preceding claims, characterized in that the transformer (s) (Ta, Tb) provide direct current electrical isolation, between the control device (4) and the switching circuit (3 ).  6) Power supply device according to one of the preceding claims, characterized in that the switching circuit (3) comprises at least four switches (Q1, Q2, Q3, Q4) associated in groups of two, each group of switches ( Q1, Q4 and Q2, Q3> being controlled using a different transformer (Ta, Tb).  7) A supply device according to claim 6, characterized in that the switches are transistors (Ql, Q2, Q3, Q4).  8) Power supply device according to one of claims 6 or 7, characterized in that it comprises means (T1, T2, T3, T4) for inhibiting the control of the switches of one of the groups (Q1, Q4 ) when the switches (Q2, Q4) of the other group are controlled.  9) Device according to claim 8, characterized in that the means for inhibiting comprise at least four transistors (T1, T2, T3, T4) said authorization each associated with a switch (Q1 to Q4), the authorization transistors associated with the switches (Q1, Q4) of the same group being actuated by the transformer (Ta, Tb) used to control the switches (Q2, Q3) of the other group.  10) Supply device according to one of claims 8 or 9, characterized in that it further comprises second means (C1, C2, C3, C4) for prolonging the inhibition of the switches (Q1 to Q4), in order to achieve a delay called "dead time" during the conduction of each group of switches (Q1, Q4 and Q2, Q3).  11) Power supply device according to claim 7, characterized in that the switches (Q1 to Q4) are transistors whose gate (G) or base is controlled by a voltage (VC, VC ') delivered by a secondary winding ( Sal, Sbl) of one of the transformers (Ta, Tb).  12) Supply device according to one of the preceding claims, characterized in that the control device (4) comprises a first and a second generator (10, 15) of signals respectively delivering a first and a second cyclic signal (CY1 , CY2), the frequency of the first cyclic signal (CY1) corresponding to the frequency at which the polarity inversions of the supply voltage applied to the electrical element follow one another.  13) Power supply device according to claim 12, characterized in that the frequency of the second cyclic signal (CY2) is lower than that of the first cyclic signal (CY1), and in that the control device (4) comprises at least a logic circuit (CL1) making it possible to produce first control signals (SC1) resulting from a cutting of the first cyclic signal (CY1) by the second (CY2), the first control signals (SCI) being applied to the grid or base of a control transistor (TC1) in order to cause the passage of a current in the primary winding (Pa) of a transformer (Ta).  14) Power supply device according to claim 12, characterized in that it comprises a second logic circuit (CL2) making it possible to produce second control signals (SC2) resulting from a cutting of the first cyclic signal (CY1) by the second (CY2), the two control signals (SC1, SC2) having logic states ("0", "1") reversed with respect to each other, the second control signals (SC2) being applied to the gate or base of a second control transistor (TC2) in order to cause the passage of a current in the primary winding of a second transformer (Tb).  15) A feeding device according to any one of claims 12 or 13 or 14, characterized in that it further comprises third means (C9, C9 ') to initialize the start of the dead time with respect to the changes of state ("Q", "1") of the first cyclic signal (CY1).  16) Power supply device according to one of the preceding claims, characterized in that the voltage source (SC) is a DC voltage source.