FR2591044A2 - Interference-suppression electronic transformer - Google Patents

Abstract

The invention relates to devices of the electrical power converter type capable of ensuring the adapting, for example, of the voltage of an AC network to the proper operating voltage required by certain commonly used appliances, this without calling upon heavy and bulky ferromagnetic transformers. The device comprises a transformer 9 one winding of which is mounted in series with the primary of the microtransformer 17. This circuit is inserted between the midpoints of the two branches of a bridge which consists of the series of transistors 20 and 23 and the series of capacitors 27 and 30. The control microtransformer 17 drives the alternating conduction of the said transistors. A trigger cell comprising the capacitor 26, the resistor 25 and the diac 24 initiates operation of the oscillator, whilst allowing a gradation in the average output voltage. Among the most interesting applications of the invention may be cited the supplying, from the mains, of low-voltage halogen lamps, laboratory supplies, miniature battery chargers, etc.

Description

 The present invention relates to electronic devices of the potential converter type, making it possible to adapt the voltage of a source, AC or DC, to the operating voltage of a given receiver, this with a yield close to the unit. for a vclume and a weight treks lower than conventional errornagnetic transformers.

 In known devices of this kind commonly called "electronic transformers", to adapt for example, the yotentif1 of the alternating network to that of a low-voltage incandescent lamp, the current is rectified and filtered at 50 or 60 Hz 120 or 220 V in order to power a high frequency oscillator whose output is coupled to a ferrite transformer, step-up or step-down, which carries out the energy transfer while ensuring the proper ratio between the voltages of alir, entation and The main advantage of such devices is that it knows that a low mass of ferrite makes it possible to transform a given power with very few losses, which a large ferromagnetic mass can achieve at the cost of high psrts. If such devices are satisfactory in principle, they are much less so in their practical execution. Fn indeed, the principle of cutting a current is bin known theoretically, but the realization of an autonomous apparatus, of low weight and dimensions, without big losses and especially of a return cost likely to compete with a trans-Torn- conventional generator, has not yet resulted, to date, in a reliable product. Thus, do we confine ourselves, currently to realizations called "switching power supplies", intended to supply, from the sector, the voltages multiples under strong powers which requires, for example, the operation of a modern television set. With such devices, an appreciable gain in weight and volume is obtained compared to a conventional transformer, but their cost price is high, so that the application which is made of it is limited to very marginal sectors of the industry.

The electronic transformer according to the invention avoids this drawback. The electronic module which constitutes 1 only contains about fifteen perfectly standard components, the short of which is attached to the assembly cost, makes it possible to envisage manufacturing an electronic transformer at a cost price lower than the cost price of a ferromagnetic transformer of equivalent power. With identical output characteristics, its additional advantages are as follows: weight 15 times lighter, volume 6 times less, gain
in electrical efficiency as well as absence of noise in operation and emission of coming parasites.

 According to a first variant. illustrated in Figure 1. attached, the voltage from the AC sector is applied between terminals 1 and -2. Via the current limiting resistor 3 4 and the filtering inductor 3, said line voltage is found. applied between one of the branches of the rectifier bridge constituted by the diodes 5, 6, 7 and 8. The voltage thus rectified is then applied between the non-common electrodes of the two capacitors 27 Ft 30 connected in series. These capacitors are chosen with equal values and their common electrode therefore behaves, from an alternative point of view, like the midpoint of the series circuit they constitute. This midpoint is connected by the primary 13 of the transformer 9 to 1 common electrode, both to transistor 20 and to transistor 23. These transistors, connected in series, are connected by their electrodes opposite the non-common electrodes of the capacitors 27 and 30 so that said transistors and said capacitors constitute a bridge between them of which they form respectively, one and the other branch. The electrode common to one and the other of the transistors 20 and 23 is also used as an output electrode, both for the. transistor 20 and for transistor 23-. The alternating control of said transistors 20 and 30 is respectively ensured by the windings 15 and 16 belonging to the micro-transformer 17. These two windings are wound on a ferrite bead of a few millimeters in length, the central hole of which is crossed by an insulated wire. primary winding location.

 The primary winding 14 of the micro-transformer 17, follow this embodiment, is connected in series with the secondary 12 of the power transformer 9. The streak circuit thus constituted by said windings is connected effectively to each of the midpoints of said bridge, namely : on one side the ccmmKaes output electrodes of transistors 20 and 23, and on the other hand, the common electrodes of capacitors 27 and 30. The relative direction of rokina-te these windings 15 and 16, is chosen from tf lic sort that an impulse of given polarity passing through: the primary winding 14, as well as the winding 12, induces between the terminals of the windings 15 and 16 opposite pulses in phase. In this way, the base-emitter space of the transistors 20 and 23, connected in parallel, respectively, between the terminals of the windings 15 and 16, ensures the alternating conduction of the collector-emitter space of said transistors.

Thus, when a current flows in a given direction in the primary 14, this current triggers the conduction of one of said transistors for a time proportional to the capacity of its base-emitter space and the inductance which is associated in parallel. Once this time has elapsed, said transistor turns off, while its collector current has generated a control pulse of the second transistor, which in turn becomes conductive. The cyclic alternating conduction of the transistors 20 and 23 therefore supplies, from the mains current rectified by the bridge of the diodes 5, 6, 7 and 8, the oscillating circuit constituted by the inductors 15 and 16 associated with the base-emitter capacities of the transistors The alternating current thus generated, discharged to ground through the bridge of capacitors 27 and 30.

Indeed, the impedance of these capacitors is low, given the fact that the frequency of the device oscillating on the capacitances and inductances considered, is high.

As the Clean inductance of the control winding 14 is very low compared to that of the winding 12, the energy it absorbs is very low compared to that which the inductance of the winding 12 of the transformer 9 can restore. The static circuit of the transformer 9 therefore stores most of the energy which is discharged at a higher or lower voltage than the supply voltage via the secondary winding 12 between the terminals of exit 10 and 11.

When the mains terminals 1 and 2 are energized, the capacitors 27 and 30 would charge at the peak voltage of the sector, without the oscillation process described above having been able to begin. Indeed. transistors 20 and 23 se. are in a state of blockage because their base space is: guardian Shunted by 1 '
rpzAanc almost zero the their command inductance res
respective. For Tue the oscillation process described above can be established, it is therefore necessary to initiate the conduction of one or other of the transistors 20 and 23. For this fairF, a trigger cell comprising the capacitor .26, the resistor 25 and the diac 24, provides the trigger pulse che.mcnt rechcrrché The high value resistor 5 charges the low value capacitor 26 and as soon as the voltage across the latter has reached the diac switching voltage 24, a high current pulse crosses the inductor 16. The instantaneous voltage developed between the terminals of said inductor is sufficient to ensure the unlocking of the base-emitter space of the transistor 23 which is coupled to it in parallel. The oscillation process can then begin.

The diode 38 connected between the collector of the transistor 23 and one of the terminals of the capacitor 26 has the function. prohibit the charging of said capacitor as long as the circuit oscillates.

The diodes 21 and 22 have the role of establishing a double circulation of the current at the terminals of the transistors 20 and 23.

The voltage-transformed energy is then available between the
terminals 10 and 11 of secondary 12. This energy occurs under
the form of half-sine waves corresponding to the straightened sector
cut according to rectangular signals whose period is
determined by the period of oscillation.

Zener diodes 18 and 19 connected respectively on the space
base-emitter of transistors 20 and -23 have the function of limiting
ter the reverse voltage Zoolicated to a non-destructive value.

An electrostatic screen 39 is provided between the primary 13 and
the secondary 12 of the transformer 9. This screen allows sup
override radio radiation that could be emitted by
the conductors connected to terminals 10 and 11.

The diodes 28 and 29 respectively connected in parallel on the
terminals of capacitors 28 and 30, have the function of avoiding
subjecting said capacitors to a voltage inversion which
would be detrimental to their reliability.

According to a second version of the device, object of the invention
tion, illustrated by Figure 2 attached, the circuit described previously is modified according to the following points.

The primary 14 of the micro-transformer 17 is no longer inserted in series with the secondary 12 of the power transformer 9, but in series with its primary 13. The operation remains otherwise similar.

A capacitor 33 can be optionally connected between the polarized terminals of the diode bridge 5,6,7 and 8, this capacitor ensuring the smoothing of the rectified mains voltage, which can be advantageous in certain cases.

The low-value capacitors 31 and 32 respectively connecting the terminals 11 and 10 of the secondary 12 to one of the terminals of the rectified sector, have the function of ensuring the decoupling of the parasitic frequencies high to ground, thereby inhibiting the discharges hert ziens that could be carried by the output circuit of the transformer 9.

The capacitors 34 and 35 connected respectively between collector and base of the transistors - 20 and 23, have the function of ensuring an energetic feedback on the high frequency switching parasites. In this way, the circuit in operation, practically no longer causes interference.

 According to a third version of the device, object of the invention, illustrated by FIG. 3, appended hereto, the circuit described above is only modified in the following points.

The output electrodes of the transistors 20 and 23 are no longer directly connected to each other, but connected respectively to one of the ends of the primary 13 of the transformer 9, this primary being provided with a midpoint, which is itself connected to the midpoint of capacitors 27 and 30 connected in series. This arrangement has the advantage of causing said semi-primaries 13 to pass through only with a current of given polarity, which limits losses by film effect.

A potentiometer 36 connected between one of the resistance terminals 25 and the opposite supply terminal makes it possible to ensure the variation of the charging time constant of the capacitor 26 which is connected to the terminal of its cursor. In this way, it is possible to delay the triggering of the diac 24, which makes it possible to ensure the gradation of the power delivered by the secondary 12 of the transformer 9, by controlling the phase angle of said triggering with respect to the mains voltage.

A capacitor 40 connected between one of the terminals of the resistor 4 and one of the terminals of the inductor 3 has the role of perfecting the elimination of the parasitic discharges sector.

The purpose of the capacitor 37 connected between one of the poles of the sector and one of the terminals of the triggering capacitor 26 is to eliminate any interference which occurs when such a device is used with a conventional external dimmer. In fact, said capacitor acts as a feedback on the charge of capacitor 26, ensuring that it is triggered wisely.

 The device, object of the invention, can be used in all cases where it is desired to transform the voltage of a direct or alternating source, into a voltage, variable or not, continuous or not. It can be used in the production of laboratory power supplies, power supply of low-voltage halogen lamps, power supply for broadcasting devices, etc., its use being characterized by a very small footprint, a very advantageous weight , excellent electrical efficiency, total absence of audible noise, very low self-heating, and finally sector or radio frequency discharges which may be low enough to meet the standards existing in this field. I1 can also be controlled from the outside by an external dimmer, without annoying phenomena of pa pil lots.

 As is obvious, and as it follows moreover, already from the above, the invention is in no way limited to those of its envisaged embodiments, it embraces, on the contrary, all variants.

Claims (12)

 1. Electrical energy converter device comprising two transistors 20 and 23 mounted in series and two capacitors 2s and 30 also mounted in series, the two series thus formed constituting the two branches of a bridge circuit whose common terminals are connected to a polarized power source, while the non-common terminals of said bridge, that is to say the midpoint of the capacitors in series, as well as the midpoint of the transistors in series, are connected together through a winding of a power transformer 9 which ensures the adaptation of the output voltage, characterized in that said winding A slt the primary 13, or the secondary 12, is mounted in series with the primary 14 of a control transformer 17 whose secondary 15 and 16 respectively provide a signal opposite in phase to the control elctro of the transistors 20 and 23 to which they are connected, characterized in that a tripping circuit comprising the at resistance 25, capacitor 26 and diac 24 initiate the oscillator thus formed.  2. Device according to claim 1, characterized in that the diodes 21 and 22, suitably polarized, are connected between, respectively, the collector and the lump of the transistors 20 and 23.  3. Device according to claims 1 and 2, characterized in that the Zener diodes 18 and 19, suitably polarized, are connected between, respectively, the base and the emitter of the transistors 20 and 23.  4. Device according to claims 1,2 and 3, characterized in that the diodes 28 and 29, suitably polarized, are connected, respectively, In parallel with the capacitors 27 and 30.  5. Device according to claims 1,2,3 and 4, characterized in that one or two capacitors 31 and 32 is connected between the output terminals of the transformer 9 and one of the terminals of the power source . is connected between the output terminals of the transformer 9 and one of the terminals of the power source.  6. Device according to claims 1,2,3,4 and 5, characterized in that a diode 38, suitably polarized is connected between the midpoint of the transistors 20 and 23 connected in series and the non-common terminal of the capacitor 26 .  7. Device according to claims 1,2,3,4,5 and 6, characterized in that a filtering inductor 3, associated or not with a filtering capacitor 40, are mounted respec strongly in series and in parallel on the power source.  8. Device according to claims 1,2,3,4,5,6, and 7, characterized in that a dimming potentiometer 36 is inserted between the resistor 25 and the capacitor 26 so as to modify the angle of diac trigger phase 24.  9. Device according to claims 1,2,3,4,5,6,7 and 8, characterized in that a capacitor 37 connected between one of the terminals of the power source and one of the terminals of the capacitor 26 provides a feedback which tends to eliminate the interference caused by an external dimmer.  10. Device according to claims 1,2,1, a, 5,6,7,8 and 9, characterized in that the inductors 15 and 16 can belong, or not, to the same magnetic circuit.  11. Device according to claims 1,2,3,4,5,6,7,8,9, and 10, characterized in that the output electrodes of the transistors 20 and 23 are respectively connected to one of the terminals a primary winding 13, which has a primary midpoint which is connected to the midpoint of the capacitors 27 and 30 connected in series.  12. Device according to claims 1,2,3,4,5,6,7,8i9,10 and 11, characterized in that two capacitors 34 and 35 connected respectively between the collector and the base of the transistors 20 characterized by fact that two capacitors 34 and 35, respectively connected between the collector and the base of the transistors 20 and 23, provide an energetic feedback aiming at eliminating the switching parasites.