FR2543756A1 - Method and device intended for converting the voltage from a DC voltage source - Google Patents

Abstract

Method and device for converting voltage from a DC voltage source with the aid of a transformer 21 having a primary winding 23 and a secondary winding 26 of two power transistors 28, 29 and of two secondary transistors 30, 31 which are provided in particular to dispel the charges stored in the base of the power transistors 28, 29.

Description

"Method and device for converting the voltage of a
DC voltage source ".

The present invention relates to a method and a dispo
sitîf intended for the conversion of the tension of a tension source
; continuous by means of a transformer presenting a core in a magnetic material, a primary winding in two parts electrically
in series and capable of being supplied with alternative energy
electric and a secondary winding capable of supplying transformed electrical energy, these method and device having the aim of transforming a positive or negative direct voltage either into an alternating voltage of different amplitude or, after rectification and possible
Lely filtering of this AC voltage into a DC voltage
of positive or negative polarity and different amplitude of the amplifier
study of the initial supply voltage.

 - There are currently known self-oscillating DC voltage conversion devices whose self-oscillation is allowed thanks to two transistors mounted respectively at the ends of the two parts of the primary winding whose midpoint is connected to the supply voltage and with two resistors each connected between the base of one of the transistors and the end of the part of the primary winding associated with the other transistor, respectively. This device has many drawbacks and, in particular, when switching the power on the two parts of the primary winding, alternately, the magnetic circuit is saturated, the two transistors are simultaneously saturated and drive simultaneously. It follows that the transistors must withstand very large currents and consequently heat up considerably.

 In another known DC voltage device, attempts have been made to remove the charges from the transistors at the time of switching by means of an auxiliary winding. In this device, however, the two transistors drive simultaneously during the switching.

 In another known DC voltage conversion device, an auxiliary transformer is associated with the bases of the transistors to avoid saturation of the magnetic material. Switching is then carried out when the auxiliary transformer is saturated. This known device has the drawback of using a second transformer and, as in the previous devices, the two transistors conduct simultaneously at the time of switching.

To avoid saturation of the magnetic material, it has also been proposed to control the base of the transistors by an external device. The DC voltage conversion device thus designed does not however solve the problems of zsimultanee saturation of the
transistors during switching.

 The present invention aims in particular to remedy the drawbacks of the state of the art.

 It first proposes a method for converting the voltage of a DC voltage source using a transformer having a primary winding in two parts electrically in series and capable of being supplied with electrical energy and a secondary winding capable of supplying transformed electrical energy, in which the parts of the primary winding are capable of being supplied with electrical energy through two power transistors, the transmitter and the collector of both are, respectively> connected in series with one and the other of the parts of the primary winding and in which one acts on the basis of the power transistors with a view to alternately supplying the parts of the primary winding.

 In accordance with the present invention, this method is such that it also consists in removing, at the time of their switching and with a view to their desaturation, the charges stored in the base of said power-transistors through two transistors respectively connected to the base of said power transistors.

 According to the present invention, this method can also consist in not allowing saturation of one of said power transistors until the other is completely desaturated.

The present invention also relates to a device for converting the voltage of a direct voltage source, of the self-oscillating type, for implementing the above method. This conversion device comprises a core transformer made of a magnetic material - having a primary winding in two parts electrically in series and a secondary winding, two power transistors whose emitter and collector of each are connected in series with l one of the parts of the primary winding, respectively, on the DC voltage source, and such a tool further comprises two secondary transistors, the emitter and the collector of each of which are connected in series with a resistor on the voltage source continuous and whose common point between each of the secondary transistots and the associated resistance is connected to the base of one of said power transistors respectively, and deu :: resistors each of which is connected between the base of one of said secondary transistors and the point common between the power transistor and the part of the primary winding associated with this secondary transistor, respectively
The present invention also relates to a device for converting the voltage of a direct voltage source of the piloted or controlled type intended for implementing the method according to the present invention and comprising, as before, a core transformer made of a material magnetic having a primary winding in two parts electrically in series and a secondary winding as well as two power transistos whose emitter and collector of each are connected in a hitch with one of the parts of the primary winding, respectively, on the source of DC voltage.

 In a variant, this DC voltage conversion device further comprises two secondary transistors, the emitter and the collector of each of which are connected in series with a resistor on the DC voltage source and the common point of which is between each of the secondary transistors and the associated resistor is connected to the base of one of said power transistors, respectively, and a switching control circuit capable of supplying, at the base of said secondary transistors, alternately, periodic signals phase-shifted with respect to the another of a half period.

In another variant, the aforementioned DC voltage conversion device is such that it further comprises two secondary transistors, the emitter and the collector of each of which are connected between the base of one of said power transistors and the pole of the associated DC voltage source, respectively, two resistors each connected between the base of one of the power transistors and the common point between the other power transistor and the part of the primary winding associated with it, and a circuit of a suitable switching command will supply, on the basis of said secondary transistors, alternately, periodic signals phase shifted with respect to each other by half a period
The DC voltage conversion device according to the present invention can also comprise, in a particularly advantageous manner, means for simultaneously blocking said secondary transistors, in the street from its stop.

 In an alternative embodiment, said power transistors may further be formed by transistors commonly called DARLINGTON.

The present invention will be better understood from the study of voltage conversion devices of a continuous voltage source, described by way of nonlimiting examples and illustrated by the drawing in which
- Figure 1 shows the electronic diagram of a DC voltage conversion device of the self-oscillating type;
- Figure 2 shows the electronic diagram of a first alternative embodiment of a continuous voltage conversion device of the piloted or controlled type
FIG. 3 represents the electronic diagram of a second wariant of a DC voltage conversion device of the piloted or controlled type,
"'n referring to FIG. 1, it can be seen that a DC voltage conversion device has been shown generally identified by the reference 1 and comprising a transformer generally identified by the reference 2.

This transformer 2 comprises a core 3 made of a magnetic material, a primary winding 4 having two parts 5 and 6 whose midpoint is connected to the DC supply voltage source VA and a secondary winding 7th This transformer 2 has the function of transform the supply voltage VA into an alternating voltage appearing, in the example, at the ends of the secondary winding 7s, this alternating voltage being directed towards a circuit of any use 80
In order to operate the transformer 2, the conversion device I comprises two power transistors 9 and 10 whose collectors are respectively connected to the ends of parts 5 and 6 of the primary winding 4 and whose transmitters are respectively connected to the ground, two secondary transistors 11 and 12 whose collectors are respectively connected to the base of the power transistors 9 and 10 and to the supply voltage by means of resistors 13 and 14 and whose emitters are respectively connected to ground, as well as two resistors 15 and 16 respectively connecting the base of the secondary transistor 11 to the collector of the transistor
of power 9 and the base of the secondary transistor 12 at the collector of the
power transistor 10.

The DC voltage conversion device 1 shown in Figure 1 is designed to operate by self-oscillation
Latin, the power transistors 9 and 10 being alternately saturated and blocked, it being understood that one is blocked when the other is
saturated. It works as follows.

Suppose that the power transistor 9 is saturated
and that the power transistor 10 is blocked. T1 follows that the
collector of the power transistor 9 is grounded and the col-
drive of the power transistor 10 is at a potential equal to twice the supply voltage "M the current flowing in part 5 of the primary winding 4.

 when the magnetic material 3 reaches saturation, the power transistor 9 becomes desaturated and the potential of its collector crott sers twice the supply voltage VA, the secondary transistor it becomes saturated through the resistor 15 and blocks the transis tor of power 9 * In me "" me time, there is an inversion of the flux in the transformer 2, this inversion of flux having allowed the blocking of the secondary transistor 12 through the resistor 16 and consequently the saturation of the power transistor 10 , it being understood that at the time of the flow reversal the potential of the collector of the power transistor 10 passes twice the supply voltage VA to earth The current then flows in part 6 of the primary winding 4 When the magnetic material 3 again reaches saturation, symmetrical switching of the power transistors 9 and 10 occurs, and so on.

It should be noted that the DC voltage conversion device 1 shown in FIG. 1 provides reduced power dissipated in the resistors 15 and 16 allowing oscillation thanks to the secondary transistors 11 and 12. In addition, the currents col ' readers of the secondary transistors i1 and 12 allow rapid evacuation of the charges stored in the bases of the power transistors
9 and 10 so that the switching times are short.

In addition to the shutdown of the tensio conversion device
1 shown in Figure 1, there is provided a circuit 17 capable of simultaneously supplying the base of the secondary transistors 11 and 12
through resistors l8 and 19 a signal saturating these transistors
secondary 11 and 12 so that the conversion device 1
is blocked or stopped as a whole "" and.

Referring to Figure 2, we see that we have represented
sensed a DC voltage conversion device generally identified by the reference 20 and comprising, as in the example shown in Figure I, a transformer identified with a general strap by the reference 21 formed of a core a magnetic material
22, a primary winding 23 in two parts 24 and 25 electrically in series and whose midpoint is connected to the DC supply voltage VA and a secondary winding 26 whose ends are
connected to a user circuit 27.

As before, the DC voltage conversion device 20 shown in FIG. 2 comprises power transistors 28 and 29 whose collectors are respectively connected to the ends of parts 24 and 25 of the primary winding 23 and whose transmitters are respectively connected to ground as well as two secondary transistors -30 and 31 whose collectors are respectively connected to "the ground of power transistors 28 and 29 and whose
transmitters are respectively connected to ground, and resistors 32 and 33 respectively mounted between the base of the transistors 28 and 29 and the supply voltage VA.

This time, the bases of the transistors 30 and 31 are respectively connected to two outputs of a switching control circuit 34 by means of resistors 35 and 36, this switching control circuit 34 being designed so as to provide alternately at the bases of the secondary transistors 30 and 31 of the peri-signals
diodes phase shifted with respect to each other by a half period, for example square signals.

The conversion device 20 shown in the figure
2 operates, at the time of switching, in the following manner.

 Suppose that the signal supplied to the secondary transistor 30 is in the high state and that, consequently, the signal supplied by this circuit 34 to the secondary transistor 31 is in the low state.

 It follows that the secondary transistor 30 is saturated, that the secondary transistor 31 is blocked and that, consequently, the power transistor 28 is blocked and the power transistor 29 is saturated The collector of the power transistor 28 is therefore has "a potential equal to twice the potential of the supply voltage VA while the collector of the power transistor 29 is grounded and the collector current of the power transistor 29 flows in the part 25 of the primary winding 23.

When the switching control circuit 34 switches, that is to say that the signal which it supplies to the base of the transistor
secondary 30 passes from its high state to its low state and that the signal which it provides to the secondary transistor 31 passes from its low state to "'its high state, the secondary transistor 30 is blocked and the secondary transistor 31 becomes saturated As a result, the power transistor 28 becomes saturated and the power transistor 29 is blocked. Consequently, the collector of the power transistor 28 goes to ground and the collector of the pulse transistor 29 goes to "potential". equal to twice the supply voltage VA while the collector current of the power transistor 28 begins to flow in the part 24 of the primary winding 23.

 On the next switching of the switching control circuit 34, the conversion device 20 will switch symmetrically, and so on.

Particularly advantageously, the period of the switching signals of the switching control circuit 34 is chosen so that the magnetic material 22 never arrives.
saturation.

As in the previous example> at the time of the switching operations, the charges stored respectively in the bases of the power transistors 28 and 29 are evacuated by means of the collector currents of the secondary transistors 30 and 31 so that they cannot
from the saturated state to being blocked very quickly.

With a view to stopping the conversion device 20 shown
seen in FIG. 2, it can be seen that a blocking circuit 37 has been provided, the outputs of which are respectively connected to the bases of the secondary transistors 30 and 31 by means of resistors 38 and 39, this
blocking circuit 37 able to supply the transistors with base
daires 30 and 31 a saturation signal of these transistors having for
Consequently the simultaneous blocking of the power transistors 28 and 29.

Referring to Figure 3 we see that we have represented
a DC voltage conversion device identified in one way
general by the reference 40 which differs from the conversion device 20 represented in FIG. 2 only by Br. fact that the resistors 32 and 33 are replaced by resistors 41 and 42, the other constituent elements of the conversion device 40 common with the constituent elements of the conversion device 20 bearing the same references.

 In this example, the resistor 41 is connected between the base of the power transistor 28 and the collector of the power transistor 29 while the resistor 42 is connected between the base of the power transistor 29 and the collector of the power transistor 28.

 The purpose of these resistors 41 and 42 thus mounted is to avoid the risk of simultaneous conduction of the power transistors 28 and 29 which could exist in the conversion device 20 shown in FIG. 2. Indeed, as long as the transistor power 29 remains saturated, its collector remained at the massa and no current flows in the base of the power transistor 28 through the resistor 41, thus leaving the power transistor 28 in the blocked state.

 When finally the power transistor 29 passes from the saturated state to the blocked state, the current progressively increases in the resistor 41 thus ensuring the synchronization of the respective changes of state of the power transistors 28 and 29. During jazz switching Next, the process is symmetrical thanks to, resistance 42.

 The voltage conversion devices of a DC voltage source described above can have many applications. They can, for example, be used for obtaining, after rectification and filtering, one or more continuous amplification voltages, chosen and dependent on the number of turns of the transformer from a continuous voltage VA. This application allows, among other things, the production of a capacitive discharge electronic ignition circuit for the engines of motor vehicles. In fact, it is possible to charge a capacity under a direct voltage for example of 400 Volts during the breaker closing cycle from of the battery voltage of 12 Volts. This capacity is then discharged into the primary of the coil using a thyristor triggered by the opening of the breakers.

It should be noted that the conversion device used must be stopped during the conduction of the thyristor by the means provided above.

The DC voltage conversion devices described above are particularly suitable for using, as power transistors 9, 10, 28, 29, transistors called
DARLINGTON.

 The present invention is not limited to the devices and the use described above. Other variants are possible without departing from the scope of the present invention defined by the appended claims

Claims (8)

 1. Method for converting the voltage of a DC voltage source using a transformer having a primary winding (4, 23) into two parts electrically in series and capable of being supplied with electrical energy and a winding secondary (7, 26) capable of supplying transformed electrical energy, in which the parts of the primary winding are capable of being supplied with electrical energy through two power transistors (9, 10, 18, 29) including an emitter and the collector of one and the other are, respectively, connected in series with one and the other of the parts of the primary winding and in which one acts on the basis of the power transistors (9, 10> 28, 29) in we to alternately supply the parts of the primary winding, characterized in that it also consists in evacuating, at the time of their switching, in view of their desaturation> the charges stored in the base of the power transistor a u through two transistors (11, 12, 30, 31) respectively connected to the base of these power transistors.  2. Method according to claim 1, characterized in that it also consists in 'authorizing saturation of one of said power transistors only when the other power transistor is completely desaturated.  3. Device for converting the voltage of a direct voltage source, of the self-oscillating type, for implementing the method according to one of claims 1 and 2, comprising a transformer (2) with a core made of a magnetic material having a primary winding in two parts (5, 6) electrically in series and a secondary winding (7), and two power transistors (9 10) of which the transmitter and the collector of each are connected in series with one of the parts of l Primary winding, respectively, on the DC voltage source, characterized in that it further comprises two secondary transistors (11, 12), the emitter and the collector of each of which are connected in series with a resistor (13> 14 ) on the DC voltage source and whose common point between each of the secondary transistors (11, 12) and the associated resistance (13, 14) is connected to the base of one of the power transistors (9, 10), respectively , and two resistors (15, 16) of which c each is connected between the base of one of said secondary transistors (11, 12) and the common point between the power transistor (9, 10) and the part (5, 6) of the primary winding (4) associated with this secondary transistor, respectively.  4. Device for converting the voltage of a DC voltage source, of the piloted or controlled type, for implementing the method according to one of claims 1 and 2-, comprising a transformer (with a core made of a magnetic material having a primary winding (23) in two parts (24, 25) electrically in series and a secondary winding (26), and two power transistors (28, 29) whose transmitter and collector of each are connected in series with a parts of the primary winding, respectively, on the DC voltage source, characterized in that it further comprises two secondary transistors (30, 31), the emitter and the collector of each of which are connected in series with a resistor (32, 33) on the DC voltage source and whose common point between each of the secondary transistors and the associated resistor is connected to the base of one of said power transistors (28, 29), respectively, and a circuit of switching command it is (34) able to supply at the base of said secondary transistors (30, 31), alternately, periodic signals phase shifted with respect to each other by a half period  5. Device for converting the voltage of a direct voltage source, of the piloted or controlled type, for implementing the method according to one of claims 1 and 2, comprising a transformer (21) with a core made of a magnetic material having a primary winding (23) in two parts (24, 25) electrically in series and a secondary winding (26), and two power transistors (28, 29) whose transmitter and collector of each are connected in series with one of the parts of the primary winding, respectively, on the DC voltage source, characterized by the fact that it also comprises two secondary transistors (30, 31) whose emitter and collector of each are connected between the base of one of said power transistors (28, 29) and the ptle of the DC-associated voltage source, two resistors (41, 42) each connected between the base of one of said power transistors (28, 29) and the common point between the other power transistor and l part of the primary winding associated therewith, and a switching control circuit (34) capable of supplying, at the base of said secondary transistors, alternately, periodic signals phase-shifted with respect to each other within a half period .  6. Voltage conversion device according to any of claims 3 and 5, characterized in that it further comprises means (17, 37) for simultaneously saturating said secondary transistors with a view to its stopping.  7. Voltage conversion device according to any one of claims 3 and 5, characterized in that said power transistors (9, 110, 28, 29) are DARLINGTONs.  8 Application of the device according to any one of claims 3 to 7 to the supply of a DC voltage intended for the ignition circuit of a vehicle engine.