FR2907615A3 - High direct voltage generating electronic device for motor vehicle, has adjusting unit adjusting control of static switches of resonant inverter according to measurement of current, where inverter generates alternating voltage - Google Patents

Abstract

The device has a resonant inverter (10) generating alternating voltage from a low voltage continuous voltage source and has split bridges (11, 12) with static switches (15- 19). A step-up transformer (20) has a winding (21) connected to an outlet of the inverter and generates an alternating voltage at terminals of another winding (23). A current sensor (36) measures current consumed by an applicative charge (40). An adjusting unit adjusts a control of the switches of the inverter according to measurement of current.

Description

1 ELECTRONIC DEVICE FOR GENERATING A VERY HIGH VOLTAGE CONTINUES

  TECHNICAL FIELD The invention relates to the field of electrical equipment installed in motor vehicles. More specifically, it relates to a device for generating a high DC voltage of the order of several tens of kilovolts from the voltage of the on-board vehicle network. This very high voltage can be used in various applications, including the supply of an electrostatic filter disposed in the vehicle exhaust line. The invention relates more specifically to the structure of the electronic circuit for generating this very high voltage, as well as its mode of regulation. PRIOR ART In general, the electrostatic filtration technique uses very high DC voltages to generate ionization phenomena favoring the capture of the particles to be filtered by appropriate filtering cells. Different assemblies for generating very high voltage have already been proposed and described in US 4,808,200, EP 0 034 075, GB 2 149 239, WO 90/07381, for industrial applications on fixed installations. Thus, the source of electrical energy used for this type of installation and the ac mains network, single phase or three phase. A particular constraint in the automotive field lies in the fact that the available source of electrical energy is the vehicle edge network, which delivers a DC voltage at low voltage, typically a few tens of volts maximum. In applications in the automotive field, the generation of very high voltage is described in EP 0 519 882, FR 2 680 612 or FR 2 861 802. The electronic circuit for generating a very high voltage described in US Pat. Document FR 2 611 802, comprises a resonant inverter supplied by the on-board vehicle network and which delivers an AC voltage to a step-up transformer connected in series with the oscillating circuit forming the output stage of the inverter. The secondary winding of this step-up transformer 10 supplies a capacitive voltage multiplier circuit, the output stage of which delivers the very high voltage to the consumer load. The systems known to date, and in particular those described in documents FR 2 861 802 and EP 0 519 882, operate using a voltage regulation, so as to control the duty cycle of the inverter to deliver a desired voltage at the of the consumer load. A problem arises with systems using voltage regulation in that the energy delivered to the consumer load is not really controlled, so that the phenomena due to the very high voltage generated, and in particular the effect "Corona" are not optimized. SUMMARY OF THE INVENTION The invention therefore relates to an electronic device for generating a DC voltage and / or very high voltage, from a low voltage DC voltage source of an automotive vehicle edge network. This very high voltage is intended for the operation of a consumer load such as in particular an electrostatic filter. Typically, such an electronic device comprises: a resonant inverter, which generates an AC voltage from the onboard network. This inverter comprises at least one inverter arm based on a static switch; a step-up transformer, whose primary is connected in series to the output stage of the resonant inverter. This transformer generates an AC voltage across its or its secondary windings; a capacitive voltage multiplier, mounted on a secondary winding of the transformer and generating on its output stage the high or very high voltage DC voltage across which the consumer load is connected. According to the invention, this device is characterized in that it comprises: a measuring device of the current consumed by the consumer load; Means for adjusting the control frequency of the static switches of the resonant inverter as a function of this current measurement. In other words, the invention consists in regulating the operating frequency of the resonant inverter so as to locate this frequency in a range where the power delivered by the inverter corresponds to the needs of the consuming load. The energy delivered to this load is correctly regulated, since the measurement of the current delivered at very high voltage makes it possible to control the electrostatic phenomena and in particular the "Corona" effect. The frequency control of the inverter is advantageously distinguished from conventional controls commonly used operating on the principle of amplitude width modulation (PWM or MLI) which act on the conduction time of the static switches of the inverter, at constant frequency.

  In practice, filtering elements may advantageously be interposed between the low voltage DC voltage source of the on-board network and the resonance inverter. These filtering members may include common mode filters and / or differential mode filters, in particular to comply with the electromagnetic compatibility standards. In practice, the structure of the resonant inverter may be a bridge structure, four quadrants, two inverter arms between the midpoints of which the output stage of the inverter is mounted. Thus, a complete bridge structure, which thus comprises four switches, makes it possible to limit the amplitude of the current flowing in the output stage.

Alternatively, it is also possible to replace one of the half-bridge of the inverter by a capacitive arm whose midpoint receives one of the terminals of the output stage, that is to say of the oscillating circuit. This variant makes it possible to limit the number of active components required, but generates an increase in the amplitude of the current flowing through the resonant circuit, for the same voltage of the on-board network. In practice, the output stage of the resonant inverter consists of a resonant circuit including a capacitive component and an inductive component. Alternatively, the inductive component may be formed by the leakage inductance of the primary winding of the step-up transformer. Alternatively, it is also possible to use a complementary inductive component, arranged in parallel on the capacitor of the resonant circuit. In this case, the additional natural frequency thus generated may have advantages in the case where the output power required is low on certain operating points.

With respect to the step-up stage, it is possible to use a plurality of secondary windings of the transformer, each of which is connected to a capacitive voltage multiplier. The output stages of these multipliers are then connected in series so as to obtain an overall voltage accumulating the output voltages of each of the multipliers.

It is thus possible to use lower voltage withstand components to obtain, however, an output at very high voltage. According to another characteristic of the invention, it is possible for certain secondary windings to be wound in opposition to the other secondary windings, so as to limit the maximum induction in the magnetic circuit of the transformer. Brief Description of the Figures The manner of carrying out the invention, as well as the advantages thereof, will emerge from the description of the embodiment which follows, with the aid of the appended figures in which: FIG. preferred embodiment of the electronic circuit according to the invention. Fig. 2 is a block diagram illustrating the operation of the invention, including control / command aspects. How to realize the invention As illustrated in FIG. 1, the very high voltage generation circuit according to the invention makes it possible to deliver a voltage THT (of negative polarity 20 in FIG. 1) to an application load (40), from a continuous LV voltage corresponding to the on-board network. As illustrated schematically in FIG. 1, this edge network (1) can be constituted by the battery of the vehicle battery. This voltage is of the order of ten volts, which can work up to a few tens of volts.

The LV voltage delivered between the input terminals (2, 3) of the device according to the invention is applied to a common mode filter (4), consisting of a coupled double inductor. This common mode filter (4) is related to a differential mode filter which may be constituted in different ways according to the technological constraints. Thus, in the illustrated example, the first high-capacitance capacitor (6) is a capacitor of the chemical type arranged upstream of an inductor (7), itself upstream of a pair of capacitors, namely a chemical capacitor (8) associated with a ceramic capacitor (9). The output of this differential mode filter (5) outputs the input voltage to the resonant inverter (10).

In the form illustrated in FIG. 1, this inverter consists of a bridge comprising two half-bridges (11, 12) themselves consisting of two identical inverter arms. In a variant not shown, the half-bridge (12) can be replaced by a pair of capacitors each replacing an inverter arm. In this case, the number of global components is smaller, since some active components and switching circuits are no longer needed. On the other hand, the current flowing in the inverter is of approximately double amplitude, so that the components of the inverter can have a current withstand twice as great, for the same edge network voltage. Thus, each arm mainly comprises a static switch (16) controlled by a control / control unit (35), associated with a switching aid circuit (15), typically including capacitance and resistance and in series with a switching inductance Lc. In practice, the static switches employed can be of different natures depending on the powers required. Thus, each switch may be formed of an IGBT transistor with an antiparallel diode, or alternatively a MOSFET transistor with or without an antiparallel diode. The middle points (25, 26) of the two half-bridges (11, 12) are connected to the output stage of the resonant inverter, constituted by a LC-type resonant circuit. More precisely, in the form illustrated in FIG. 1, the resonant circuit comprises a capacitor CR in series with the leakage resistor Lf of the primary winding (21) of the transformer (20).

It is possible to use an inductance consisting of a specific component in series with the capacitor CR. However, the use of transformer leakage inductance saves such a component.

In the illustrated form, the capacitor of the resonance circuit CR has a complementary inductance Lp in parallel. In this case, the natural frequency of the resonant circuit formed by the inductance Lp and the capacitor CR constitutes a singular point for which, when the inverter is controlled at an identical frequency, the transmitted power is almost zero. However, the presence of inductance Lp is not mandatory for the proper operation of the invention.

As already mentioned, the transformer (20) has a primary winding (21) and one or more secondary windings (23). In order to generate a very high voltage, the transformer (20) is of course elevator. Typically the ratio of the transformer is of the order of 1000 or more. In the illustrated form, this transformer (20) may have a plurality of secondary windings, although this is not an absolutely necessary condition for the proper operation of the invention. Each secondary winding is connected to a capacitive voltage multiplier circuit comprising a first capacitor C, two diodes D1 and D2, and an output capacitor Cs.

Of course, the capacitive voltage multiplier may comprise in cascade several cells each including two capacitors and two diodes, so as to increase the multiplication factor. In the illustrated form, the different capacitors Cs of each of the multiplier stages are arranged in series, so as to increase the overall voltage THT, while employing components having a voltage withstand corresponding to that of a unit multiplier stage.

In practice, a compromise must be found between, on the one hand, the number of cascaded cells in the voltage multiplier, and on the other hand, the ratio of the transformer. This compromise is found by seeking to minimize the parasitic losses and capacitances at the transformer, thus avoiding a too high transformation ratio. Likewise, the number of cells in the voltage multiplier arrangement must not be too large to limit the number of components required.

In the illustrated form, the secondary (23, 24) of the transformer (20) are wound in the opposite direction, so as to limit the maximum induction in the transformer magnetic circuits, and thus avoid saturation phenomena, and at the very least the high losses due to hysteresis phenomena.

To provide the characteristic current regulation, a current sensor (36) is arranged in series with the application load (40) to measure the current delivered by the characteristic device. Thus, and as illustrated in FIG. 2, the sensor (36) makes it possible to measure the current I consumed by the application load (40). This current (36) is compared to a setpoint (45) determined according to a modeling of the application load. The difference between the setpoint and the measured value of the current of the load (40) is filtered by a conventional corrector (46), of the proportional or integral proportional type, in order to produce a value at the level of the control command unit (35). frequency of operation of the inverter. This frequency value corresponds to the control frequency of the static switches of the inverter. This switching frequency may be chosen in a range extending around the natural frequency of the resonant circuit, composed of the resonance capacitor CR and the leakage inductance LF of the transformer (20).

Different modes of operation may be chosen. It is thus possible to operate in a continuous mode, that is to say below this resonance frequency, and above half of this same frequency. It is also possible to choose this frequency below half of the own resonance frequency or even above the own resonance frequency. Of course, the more the switching frequency approaches the own resonance frequency, and the higher the power transmitted is important.

It follows from the foregoing that the circuit according to the invention makes it possible to ensure effective and precise regulation of the current delivered to the application load, allowing control of the electrostatic phenomena. The invention can therefore be advantageously used in any application requiring a generator of very high DC voltage, for functions relating to the depollution, the treatment of air and / or the reforming of fuels for example.

Claims (1)

  1 / An electronic device for generating a high DC voltage, from a low voltage DC voltage source (1) of an automotive vehicle onboard network, for the operation of a consumer load (40) such as an electrostatic filter, comprising: a resonant inverter (10), generating an alternating voltage from said low voltage DC voltage source, and having at least one inverter half-bridge (11, 12) having switches static (15-19); a step-up transformer (20), whose primary (21) is connected at the output of the resonant inverter (10), and which generates an alternating voltage across the or of its secondary windings (23); a capacitive voltage multiplier (29), mounted on a secondary winding (23) of the transformer, generating on its output stage a high DC voltage UTHT, across which the load is connected, characterized in that it comprises A current measuring member (36) consumed by said consumer load (40); And means for adjusting the control frequency of the static switches (15-19) of the resonant inverter according to said current measurement; 2. Electronic device according to claim 1, characterized in that filter elements (4, 5) are interposed between the low-voltage direct voltage source and the resonant inverter. 3 / An electronic device according to claim 2, characterized in that the filtering members include a common mode filter (4) and / or a differential mode filter (5). 4 / An electronic device according to claim 1, characterized in that the inverter (10) is a four-quadrant bridge, the output stage of the resonance inverter was mounted between the midpoints of the two half-bridges 5 5 / electronic device according to claim 1, characterized in that the inverter comprises an inverter half-bridge and a capacitive arm, between the midpoints of which is mounted the output stage of the inverter. 6 / An electronic device according to claim 1, characterized in that the output stage of the resonant inverter comprises a resonant circuit combining a capacitive component CR and an inductive component Lp. 7 / An electronic device according to claim 1, characterized in that the inductive component is formed by the leakage inductance LF of the primary (21) of the transformer. 8 / An electronic device according to claim 1, characterized in that the transformer comprises a plurality of secondary windings (23, 24) to each of which is connected a capacitive voltage multiplier (19), the output stages of said multipliers being connected in series. 9 / An electronic device according to claim 1, characterized in that some of the secondary windings (24) are wound in opposition to the other secondary windings (23).