FR2555374A1 - Variable-voltage electronic transformer - Google Patents

Abstract

The invention relates to devices of the electrical energy convertor type capable of adapting, for example, the voltage of an AC network to the correct operating voltage required by certain appliances currently in use, and without calling for heavy, cumbersome ferromagnetic transformers. The device comprises an oscillating circuit consisting of the primaries 11 and 17 associated with the capacitor 10. This oscillating circuit is inserted between the midpoints of the two branches of a bridge which is constituted by the series of transistors 24 and 25 and the series of capacitors 8 and 9. A control micro-transformer 18 steers the alternate conduction of the said transistors. A triggering cell comprising the capacitor 13, the resistor 16 and the triac 20 initiates operation of the oscillator, while 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

your Pure invention concerns electronic devices - a potential converter type, allowing to adapt the
voltage from a source, alternative or direct, to the operating voltage of a given receiver, this with a pro c efficiency of the unit for a volute and a weight much lower than conventional ferromagnetic transformers.

 In known devices of this kind, commonly called "electronic transformers", to adapt, for example, the potential of the AC network to that of a low-voltage incandescent lamp, the current is rectified and filtered at 5C or 60 Hz 120 or 2o 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 by ensuring the proper ratio between the supply and output voltages. 'main advantage of such devices lies in the fact 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 electrical losses. If such devices are satisfactory in principle, they are much less so in their practical execution. Indeed, the principle of chopping a current is well known in theory, but the realization of an autonomous device, of low weight and dimensions, without big losses and especially of a cost price likely to compete with a traditional transformer, n 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, multiple voltages under high powers that requires, for example, the operation of a modern television. 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 allows this drawback to be avoided. The electronic module which constitutes it comprises only about fifteen perfectly standard components whose own cost joined to the assembly cost makes it possible to envisage the manufacture of an electronic transformer at 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 of 3io and absence of noise in operation.

 According to a first variant, illustrated by FIG. 1, attached, the voltage from the AC sector is applied between terminals 1 and 2. Via the resistor 3 for limiting current, the value of which does not exceed a few ohms, this voltage is found applied between one of the branches of the rectifier bridge constituted by the diodes 4,5,6 and 7. The voltage thus rectified is then applied between the non-common electrodes of the two capacitors 8 and 9, 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 which they constitute. This midpoint is connected by a low-value capacitor 10 to the common electrode, both to transistor 24 and to transistor 25. These transistors, connected in series, are connected by their electrodes opposite the non-common electrodes of the capacitors. 8 and 9, so that said transistors and said capacitors constitute between them a bridge of which they respectively form, one and the other branch. The electrode common to each of the transistors 24 and 25 is also used as an output electrode, both for the transistor 24 and for the transistor 25. The alternating control of said transistors 24 and 25 is provided respectively by the windings 23 and 19 belonging to the rricro-transformer 18. These two windings, like the primary winding-17, have only a few turns of insulated wire wound on a saturable ferrite core with a volume of a few tens of mm3.

The primary winding 17 of the saturable micro-transformer 18 is, according to the figure, connected in series with the pri mairs of the power transformer 1z. The series circuit thus constituted by the primaries 1? and 11 is connected in parallel on the terminals of the capacitor 1G. This assembly therefore produces a parallel oscillating circuit which is inserted between the common output electrodes of the transistors 24 and 25 and the midpoint of the series circuit constituted by the capacitors 8 and 9. The relative winding direction of the windings 17,19 is then chosen so that the pulse pulse of given polarity passing through the primary winding 17, as well as the winding 11, induced between the terminals of the windings 19 and 23 of the pulses of opposite polarity. In this way, the base-emitter space of the transistors 24 and 25, connected in parallel, respectively, between the terminals of the windings 23 and 19, ensures the alternating conduction of the collector-emitter space of said transistors.

Thus, when a current flows in a given direction in the oscillating circuit constituted by the capacitor 10 associated with the bearings 11 and 17, this current triggers the conduction of one of said transistors, when the direction of circulation of this current s' reverse in this same oscillating circuit, the first transistor entered into conduction is then blocked by a negative pulse, while the second transistor becomes conductive in turn. The cyclic alternating conduction of the transistors 24 and 25 therefore supplies, from the mains current rectified by the bridge of the diodes 4,5,6 and 7, the oscillating circuit constituted by the windings 17 and 11 associated with the capacitor 10. The alternating current thus generated in said oscillating circuit is discharged to ground through the bridge of capacitors 8 and 9.

In fact, the impedance of these capacitors is low, taking into account the fact that the resonant frequency of said oscillating circuit is high.

As the inductance Pr, operates from the control winding 17 is very low compared to that of the winding 11, the energy it absorbs is very low compared to that which the inductance of the primary winding of the transformer can absorb 12. The magnetic circuit of the transformer 12 therefore stores approximately 99.0 of said energy which can be evacuated under higher or lower voltage than the supply voltage via the secondary winding 13 between its output terminals 14 and 15.

When the mains terminals 1 and i are energized, the capacitors & and 9 would charge at the peak voltage of the sector, without the oscillation process described above having been able to begin. Indeed, the transistors 24 and 25 are in blocking state because their base-2mitter space is shunted by the almost zero impzdance and their respective control windings 23 and 19. So that the process of oscillation described above can be established, it is therefore necessary to initiate the conduction of one or other of the transistors 24 and 25. To do this, a trip cell comprising the capacitor 13, the resistor 16 and the diac 20 allows to provide the trigger for rechFrche. The high value resistor 16 charges the low value capacitor 1J through the windings 17 And 11, then the capacitor 9. As soon as the voltage across the capacitor 13 has reached the switching voltage of the diac 20, or of a component of similar function, a very short but high current pulse closes on the circuit formed by said capacitor 13, said diac 20 and the winding -17 which is mounted in series with them. A polarity pulse - given passing through the primary 17 induces in one of the Secondary 19 or 23 a pulse which triggers the chosen transistor. The triggering of the oscillation process is then engaged, and the alternating conduction of the transistors 24 and 25 is established, governed by the proper period of the oscillating circuit described above.

The energy at transformed voltage is then available between the terminals 14 and 15 of the secondary 13. This energy is in the form of a sine wave, image of the rectified sector, sine wave cut according to rectangular signals whose period is determined by the period. clean of the above oscillating circuit.

The charging time constant of the capacitor 13, taking into account the high value of the resistor 16, is very large compared to the period of oscillation of the chopping thus obtained, also, the triggering pulse described above will not be reproduced- such as about after a thousand cutting cycles. However, this pulse should not intervene badly and trigger the conduction of the transistor which must remain blocked at the instant considered. Otherwise, there would be a risk in terms of the reliability of this transistor and its counterpart. THE circuit describes this danger; in fact, the capacitor 13 can only discharge if the phase of the voltage of said oscillating circuit allows it. I1 therefore suffices to arrange the relative direction of winding of the windings 23 and 19 with respect to the polarity of the triggering pulse so that this risk of conduction against time is eliminated.

 Another advantage of the device according to the invention lies in the fact that the average power delivered between the terminals 14 and 15 can be adjusted at will by means of a simple potentiometer connected in place and placed of the resistor 16.

To obtain this result, it is necessary to give the con ns 8 and 9 values low enough so that the mains voltage is not smooth. Indeed, to obtain this gradation effect, it is necessary to play on the useful surface of the half-sine waves which will be the object of the cutting described above. To do this, it is necessary to disarm the oscillation process of the circuit by allowing the junction potential between two consecutive half-sinusoids to drop to a sufficiently low value. The discharge time constant of the decXentcent cell constituted by the capacitor 13 associated with resistor 16 and diac 20 must then be calculated so that its duration is adjusted over the period of the sector used. Thus, by increasing or decreasing the value of the potentiometer which has been substituted for the resistor 16, can we advance or delay the triggering of the chopping process, which has the consequence of increasing or decreasing the available useful power across the primary of transformer 12. On a given load connected between terminals 14 and 15, the power applied is also subject to the same variation in power. Everything happens as if the average voltage supplied across the load could be modulated by the simple operation of said potentiometer.

Such a device therefore makes it possible to produce, with excellent energy efficiency, an electronic transformer whose transformation ratio can be adjusted from a zero value to the nominal value with an almost infinite resolution.

 he device can be followed, at output, by a rectification and a filtering. It would then constitute a direct current power supply with variable voltage, economical, of a very limited weight and volume accompanied by a high electrical efficiency.

 According to a second variant of the device, object of the invention, illustrated by FIGS. 2 and 3, attached hereto, the circuit is only modified at the level of the control of the transistors.

In fact, according to this variant, this transformer is eliminated.

The control windings 19 and 23 are integrated in a particular way into the transformer 12. Indeed, conventionally, to manufacture this type of transformer, the primary 11 and the secondary 13 and possibly 19 and 23 are all wound concentrically on the central core of the circuit magnetic. The drawbacks of this type of transformer are significant, because the windings must be isolated from each other, especially if the device must meet the standardization requirements, and the connection of these 8 output wires whose inputs and outputs must be identified is not viable economically. Also, the transformer equipping the device according to the invention comprises the two power windings 11 and 13 which are wound concentrically on the central core of the transformer 12 without requiring any marking between their outputs, their reciprocal isolation being ensured by a layer of tape
Teflon, for example.

As illustrated in FIG. 3, annexed, there are the primary and secondary power windings with their respective outputs 21, 22 and 14, 15. These windings whose ratio between their number of turns is fixed can be wound with or without a carcass on the central core of the transformer 12.

As for the control windings, advantageously constituted by a wire insulated by means of a sheath, are wound independently of the power windings il and 13. As they only comprise a few turns, it is easy, once the magnetic circuit of the transformer 12 has been fixed, to wind them around one of the return legs of the magnetic circuit. In this way, it is easy, in manufacturing, to make the connection of all of the outputs of said transformer. Indeed, it then suffices to connect the two control windings 19 and 2j to the circuit, the inputs and outputs of which are easily identifiable, so that the device is in working order.

In the case of this second variant, the tripping circuit always comprises the capacitor 13 associated with the resistor 16 and the diac 20, but, here, the pulse which it delivers is supported directly on the control winding 19 or 23, on its output terminal which is common to the control electrode of the transistor concerned. As for what was described above, this pulse initiates the operation of the oscillator, with this difference, it is the pulses maintenance are sKtanues by the coupling These few turns of the windings 19 and ~ 3, have the Ens of relative winding is chosen to provide opposite pulses in phase.

 elon a third variant of the device according to the invention, the capacitors 8 and 9 are chosen with high values so that the filtering of the mains current is ensured.

The voltage across these capacitors is then substantially continuous and its value then reaches the strike voltage of the alternating sector. In this case the secondary 13 of the power transformer 12 delivers an alternating signal from which the component at 5C or 60 Hz is absent from the sector, which greatly facilitates, in the event of particular use, the smoothing of the output signal after a turnaround, for example.

The disadvantage of this solution is the fact that it is then necessary to use as capacitors models with liquid electrolyte less reliable than the plastic film or metallized paper capacitors used in the first variants.

Another drawback also lies in the fact that in the case of this latter variant, the modulation of the output voltage becomes impossible because, after triggering of the oscillation, the supply voltage no longer returns cyclically to a value close to zero.

 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 variable voltage or not, continuous or not. It can be used in the supply of laboratory power supplies, power supply for low-voltage halogen lamps, power supply for broadcasting devices, its use being characterized by a smaller footprint, a more advantageous weight, an electrical efficiency. improved, an absence of parasitic noise as well as heating.

Claims (8)

 1. Electrical energy converter device comprising two transistors 24 and 25 connected in series and two compensators 8 and 9 connected in series, the two series thus formed continuing 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, ie the midpoint of the capacitors in series and the midpoint of the transistors in series, are connected to each other through the primary 11 of a transformer adapter 12, the secondary 13 of which supplies a desired voltage on the load connected between its output terminals 14 and 15, characterized in that the said primary It is mounted in series with another primary 17 belonging to the control micro-transformer 18 , whose secondaries 19 and 23 each provide a signal opposite in phase to the control electrode of transistor 25 and 24 to which they are connected respectively, characterized by the fact that u'a capacitor 10 is connected in parallel on the series circuit formed by the primaries 11 and 17, thus constituting with them a parallel oscillating circuit inserted between said non-common terminals of the bridge, characterized in that a tripping circuit, which can optionally controlling the phase angle of a rectified sector supply, comprises a capacitor 13 having a terminal common with the secondary 17 and its other terminal common with that of the resistor 16 which is connected to one of the poles of the source power supply, the terminal common to said resistor and to said capacitor being connected to the terminal of a diac 20, or of an equivalent element, the other terminal of said diac being connected to the terminal of primary 17 which is not common to capacitor 13.  2. Device according to claim 1, characterized in that the control micro-transformer 18 is split into two separate magnetic circuits controlling the secondary 19 and 23 respectively, the primary 17 itself being split into two associated semi-primaries strongly respect each of said magnetic circuits.  3. Device according to all of claims 1 to, caracterjse in that the terminal of the capacitor 13, not common to the resistor 15 is connect to the pole of the supply source exposed to that which is common with one of the terminals of said resistor 16 and the terminal of the triac LO, or an equivalent element, which is not common to said resistor 16 and to said capacitor 13, is connected directly to the electrode of one of the secondary 19 or 23 which is common respectively to the control electrode of transistor 25 and of transistor 24.  4. Device according to all of claims 1 to 3, characterized in that the micro-transformer 18 is reduced to the control windings 19 and 23 which are wound in a relative direction ensuring the phase opposition of their output signals , this winding being carried out with a wire suitably insulated on the legs of the magnetic circuit 12 ensuring the return of the induced flux in its central core.  5. Device according to all of claims 1 to 4, characterized in that the polarized current supply is provided by a diode bridge 4,5,6 and 7 connected on the one hand to the AC sector by terminal 1 and terminal 2 via the current limiting resistor 3, and, on the other hand, by its polarized terminals, to the bridge formed between them by capacitors 6 and 9 associated with transistors 24 and 25, this supply can also be ensured by a simple diode 26 suitably polarized, the sector correction then being effected by means of terminals 27 and 28, through the current limiting resistor 29, the use of one or the other of these rectification modes, mono-alternation or bi-alternation, ensuring an advantageous means of reducing the output power of the device, another simple means of power control could be reduced to a switch putting out any of the 4,5,6 or 7 diodes making up said po nt  6. Device according to claim 5, characterized in that the resistor 16 is replaced by a potentiometer whose value suitably chosen, ensures the adjustment of the trigger point of the oscillator relative to the phase angle dK- the alternation of the sector concerned, this making it possible to ensure the progressive adjustment of the output power of the device.  7. Device according to claim 6, Characterized by the fact that a voltage smoothing capacitor 30, an electrolytic high value, is connected between the non-common terminals of the serine constituted by the capacitors b and 9.  8. Device according to all of claims 1 to 7, characterized in that the output terminals 14 and 15 are connected to the rectifying bridge composed of diodes 31, 32, 33 and 34, which delivers a rectified signal at output, filtered by the capacitor 35, this signal can then be smoothed and applied to a given load.