EP0326489A1 - Working point regulation system of a DC power supply - Google Patents

Abstract

The regulation system consists of a current generator system (1) coupled to a pulse-width modulating converter (2). <??>The system includes means (11, 12) for sampling and measuring the voltage (V) and current (I) delivered by the current generator (1), a threshold detector (3) for detecting any maladjustment of the converter (2) which delivers a logic signal (C) representative of the maladjusted or non-maladjusted state of the converter (2) with respect to the threshold values. A control loop (4) consists of a switching element (42) which, by reversing the sign of the error signal ( epsilon ), enables the operating point to be returned to the point of maximum power (Pmax) on the output current-voltage characteristic of the current generator (1). <??>Application to the control of electrical power supply circuits in space installations. <IMAGE>

Description

The present invention relates to a system for regulating the operating point of a DC power supply comprising a current generator system coupled to a pulse width modulation converter.

In the field of power supply to aircraft or space installations, the supply is most often made from generators of the current generator type, such as solar generators. These generators designated by the name of current generators have a substantially rectangular current-voltage output characteristic I (V), both a source of current in its zone (I) and a source of voltage in its zone (II), thus as shown in Figure 1a. The power-voltage output characteristic P (V) has a substantially triangular shape, as shown in FIG. 1b.

These generators are normally associated with a so-called width modulation electrical energy converter, which is controlled so as to deliver pulses of rectangular voltage of variable width as a function of the power consumed by a load circuit. This type of converter is more commonly designated in English terms by "PWM" and corresponds to devices designated under the name of "BUCK", "BOOST" or "BUCK-BOOST".

The current-voltage input characteristics I (V) of such a converter supplying a load consuming a constant power has the appearance of the positive part of an equilateral hyperbola as shown in FIG. 1c, these converters being essentially reactive, and having a very good yield, consuming only very little power.

Conventionally, the electronic control loop of these converters comprises an error amplifier comparing the voltage to be regulated, the voltage supplied to the load, to a reference voltage, the amplified error signal being supplied to a comparator ensuring the modulation of width of the voltage pulses delivered by the converter by comparing the error signal to a signal generated by a sawtooth generator. An integrator is introduced at the output of the comparator in order to obtain a zero static error.

A given converter, according to the direction of variation of the error signal as a function of the variation of the voltage to be regulated, therefore has its operating point either on zone I current source, or on zone II voltage source of the current-voltage output characteristic of the generator for a constant power consumption P, as shown in FIGS. 1d and 1e.

When the power called by the load becomes more and more important, the abovementioned operating point progressively moves over the output characteristic I (V) of the generator towards the maximum power point Pmax. likely to be supplied by the converter.

When the power demand becomes greater than the maximum power Pmax, the operating point previously, located on the current generator zone or on the contrary on the voltage generator zone, passes over the voltage generator or current generator zone, as well as represented in figure 1f and 1g, beyond or below the point of coordinates I (Pmax), V (Pmax). Under these conditions, the operating point becomes unstable because there is a change in operating regime, that is to say passage from one to the other current source area respectively voltage.

The operating point moves, due to its instability, and ends its course at the point of the current-voltage output characteristic I (V) characterized, as the case may be, either by 1 = 0, or by V = 0 and corresponds to a power supplied zero by the solar generator, which corresponds to the stall phenomenon, stable state thereof, as shown in Figure 1f and 1g.

A system for extracting the maximum power of a DC generator of characteristic I (V) substantially rectangular has been described in French patent application No. 2,031,063. This system comprises a control loop for a transistor in the converter, the transistor being controlled at variable frequency. This system does not provide a regulated voltage.

The purpose of the system for regulating the operating point of a DC power supply according to the invention is to remedy the aforementioned drawback by eliminating the stall phenomenon.

Another object of the present invention is the implementation of a regulation system of a DC power supply, in which the amplitude of the excursion of the operating point around the point of maximum power Pmax is adjustable.

Another object of the present invention is also the implementation of a system for regulating a DC power supply, in which the operating point at demanded power lower than the maximum power Pmax can be adjusted either over the area of the current source characteristic, ie in the area of the voltage source characteristic.

Another object of the present invention is finally the implementation of a system for regulating a DC power supply, in which the solar generator can be coupled to the converter without particular precautions, one of the operating points corresponding to the power actually called being automatically reached.

The system for regulating the operating point of a DC power supply, object of the invention, comprises a current generator system coupled to a pulse width modulation converter.

It is remarkable in that it comprises means for sampling and measuring the voltage (V) and the current (I) delivered by said current generator to the converter, these means delivering a signal representative of the intensity (I) and of the voltage (V), means for detecting the threshold of the stall of said converter, these means receiving the signals representative of the intensity (I) and of the voltage (V) delivered by the intensity generator and delivering a logic signal (C) representative of the state of stalling or non-stalling of the converter with respect to the threshold values, a loop for regulating the width of pulses delivered by the converter, said loop comprising means for sampling and measuring the voltage (Vc) delivered by the converter to the load, differential amplifier means receiving on a first input the signal delivered by said means for measuring the voltage delivered by the converter and on a second input a reference voltage (Ur) and delivering an amplified error signal (ε), reversing means comprising an input terminal receiving said amplified error signal and an inversion control terminal receiving said logic signal (C) delivered by said variable threshold detector means and delivering the inverted error signal (-ε), integrating means receiving the inverted or non-inverted error signal (± ε) and delivering ant an integrated error signal (S), pulse width modulation means comprising a comparator and a sawtooth generator, said comparator comprising a first input terminal receiving from said integrator said integrated error signal ( S) and a second input terminal receiving the signal delivered by the sawtooth generator, said comparator comprising an output terminal delivering a pulse width control signal from the pulse width modulation converter.

The regulation system which is the subject of the invention finds application in systems for supplying electrical energy to artificial satellites, for space aircraft and, more generally, to any system for supplying electrical energy using generators of intensity such as solar batteries, both in space and domestic.

• - la figure 2a représente un schéma synoptique du système de régulation du point de fonctionnement d'une alimentation à courant continu comprenant un système générateur de courant couplé à un convertisseur à modualtion de largeur d'impulsions,
• - la figure 2b représente aux points 1) et 2) les diagrammes de fonctionne ment du point de fonctionnement du système au premier décrochement sur la caractéristique de sortie courant-tension I(V) du générateur de courant,
• - la figure 2c représente un diagramme explicatif du fonction­nement du dispositif tel que représenté en figure 2a, de façon plus détaillée dans les étapes successives aux figures 2b 1) ou 2), lorsque la puissance appelée est supérieure à Pmax,
• - la figure 3a représente un mode de réalisation préférentiel du système de régulation objet de l'invention tel que représenté en figure 2a,
• - la figure 3b représente un diagramme de fonctionnement du point de fonctionnement du système sur la caractéristique de sortie courant-tension I(V) du générateur de courant, lorsque la puissance appelée diminue en deçà de Pmax,
• - les figures 4a et 4b représentent un mode de réalisation particulier, non limitatif, préférentiel du système objet de l'invention, représenté en figure 3a,
• - les figures 4c, 4d et 4e représentent des diagrammes explicatifs du fonctionnement du dispositif objet de l'invention tel que représenté en figure 4b.
• - la figure 5 représente un schéma fonctionnel synoptique d'une variante de réalisation de l'objet de l'invention permettant un passage systématique et immédiat du point de fonctionnement sur la zone source de tension ou sur la zone source de courant lors du passage du mode d'extraction de la puissance maximale du générateur au mode de régulation de tension,
• - la figure 6 représente de façon plus détaillée une variante de réalisation de l'objet de l'invention,
• - la figure 7 représente, dans une version simplifiée, la variante de réalisation de l'objet de l'invention précédemment représenté en figure 5.

The invention will be better understood on reading the description and on observing the drawings in which, in addition to FIGS. 1a to 1g, relating to operating diagrams of a generator of conventional type,

• FIG. 2a represents a block diagram of the system for regulating the operating point of a DC power supply comprising a current generator system coupled to a pulse width modulated converter,
• FIG. 2b represents in points 1) and 2) the operating diagrams of the operating point of the system at the first offset on the current-voltage output characteristic I (V) of the current generator,
• FIG. 2c represents an explanatory diagram of the operation of the device as shown in FIG. 2a, in more detail in the successive steps in FIGS. 2b 1) or 2), when the power demand is greater than Pmax,
• FIG. 3a represents a preferred embodiment of the regulation system which is the subject of the invention as shown in FIG. 2a,
• FIG. 3b represents an operating diagram of the operating point of the system on the current-voltage output characteristic I (V) of the current generator, when the power demand decreases below Pmax,
• FIGS. 4a and 4b represent a particular, non-limiting, preferential embodiment of the system which is the subject of the invention, represented in FIG. 3a,
• - Figures 4c, 4d and 4e show explanatory diagrams of the operation of the device object of the invention as shown in Figure 4b.
• - Figure 5 shows a block diagram of an alternative embodiment of the object of the invention allowing a systematic and immediate passage of the operating point on the voltage source area or on the current source area during the passage of the mode for extracting maximum power from the generator in voltage regulation mode,
• FIG. 6 shows in more detail an alternative embodiment of the subject of the invention,
• FIG. 7 represents, in a simplified version, the variant embodiment of the object of the invention previously represented in FIG. 5.

The system for regulating the operating point of a DC power supply which is the subject of the invention will firstly be described in conjunction with FIG. 2a.

The DC power supply is deemed to include a current generator system 1, which is coupled to a pulse width modulation converter 2. The current generator system 1 can be constituted by a solar cell system and the designation current generator system must be understood as a system whose current-voltage output characteristic is substantially rectangular, as shown in FIG. 1a.

The pulse width modulation converter 2 is coupled to the current generator system. It makes it possible to generate rectangular voltage pulses, the width of which varies as a function of the power called up by the payload CU; of course, the pulse width modulation converter includes smoothing circuits, not shown in FIG. 2a, which make it possible to deliver the DC voltage Vc to the payload CU.

In accordance with a particularly advantageous aspect of the regulation system which is the subject of the invention, it comprises, as shown in FIG. 2a, means denoted 11, 12 for sampling and measuring the voltage V and the current I delivered by the current generator 1 to converter 2. The means for sampling and measuring the voltage V and the current I can advantageously be constituted by a potentiometric system as regards the measurement of the voltage V, and a shunt or similar device, in as regards the sampling and measurement of the current I. These elements of conventional type will not be described in detail, since they are perfectly known to those skilled in the art. The sampling and measuring means 11 and 12 deliver a signal I, respectively V, representative of the intensity I and of the output voltage V of the current generator, which are applied to the input of the converter with width modulation d pulses 2.

In addition, the regulation system which is the subject of the invention comprises means 3 detectors with a threshold for the converter stalling 2. The stall state of the converter 2 has been defined beforehand on the basis of the corresponding voltages of voltage V and of current. I delivered by the current generator 1 to the converter 2 in conjunction with FIGS. 1f and 1g. The means 3 detectors at the dropout point of the converter 2, receive the signals representative of the intensity 1 and of the voltage V delivered by the intensity generator 1, to the converter 2 and delivers a logic signal C, representative of the state of the converter 2 stalling or not stalling with respect to the threshold values. It will of course be understood that the threshold values correspond either to an initially low voltage V value, or to an initially low intensity value, the comparison of the actual voltage V and intensity I value with these threshold values allowing when the values of voltage V or of current I are respectively lower than the corresponding threshold values, to highlight the off-hook or non-off-hook state of the converter 2, as a function of the power called up by the payload CU.

In addition, as shown in FIG. 2a, the regulation system which is the subject of the invention comprises a regulation loop 4 for the width of pulses delivered by the converter 2. The regulation loop 4 comprises, as shown in FIG. 2a , means 20 for sampling and measuring the voltage Vc delivered by the converter 2 to the payload CU. These means can be constituted by a potentiometric assembly similar to that already mentioned for the production of the means for sampling and measuring the voltage V delivered by the current generator 1.

The regulation loop 4 also comprises differential amplifier means 40 receiving on a first input the signal delivered by the means 20 for measuring the voltage delivered by the converter 2 and on a second input a reference voltage denoted Ur. This reference voltage is delivered by a DC voltage generator 41 suitably stabilized. This type of generator will not be described, since it calls upon normal knowledge of a person skilled in the art. The differential amplifier means 40 deliver an amplified error signal denoted ε.

In addition, reversing means 42 are provided, these reversing means 42 comprising an input terminal 420, connected to the output of the differential amplifier 40 and receiving the amplified error signal. The reversing means 42 further comprise an inversion control terminal represented diagrammatically by a switch blade denoted 421, the inversion control terminal 421 receiving the logic signal C delivered by the means 3 threshold detectors. The reversing means further comprise a direct transmission terminal 424 of the amplified error signal and a reverse transmission terminal of the amplified signal terminal denoted 425, which is connected to an inverter denoted 423. Reversing means 42 thus deliver, on switching by via the control signal C, the amplified error signal not inverted, via terminal 424 or the amplified error signal inverted via terminal 425 and the inverter 423.

Integrating means 43 are further provided, the latter receiving the inverted or non-inverted error signal, ± ε and delivering an integrated error signal denoted S.

In addition, and conventionally, means 44 for pulse width modulation are provided, these comprising a comparator 440 and a sawtooth generator 441. The comparator comprises a first input terminal receiving integrator 43 the integrated error signal S and a second input terminal receiving the signal delivered by the sawtooth generator 441. The output terminal of comparator 44 delivers a control signal denoted SCL, of pulse width of the pulse width modulation converter 2. The pulse width is controlled by the duration of the high state of the SCL signal, which is itself controlled by the time during which the sawtooth voltage delivered by the sawtooth generator 441 is less than the value of the amplified error signal inverted or not ± ε.

As will be understood from the observation of FIG. 2b, and in particular at points 1 and 2 thereof, for values of the current threshold denoted Imin and of the voltage Vmin of the means 3 detachers with drop-out threshold of the converter 2, each time converter 2 is removed, that is to say for each crossing by the operating point of the regulator of the point of maximum power Pmax on the voltage current output characteristic I (V) of voltage generator 1, one of the parameters of current I or voltage V of the operating point becomes lower than the threshold Imin or Vmin imposed, which has the effect of causing the switching of the reversing means 42. This switching itself causes a sign inversion of the signal error ε in the regulation loop 4, which has the effect of restarting the operating point of the converter 2 towards the maximum power point Pmax thereby avoiding indefinitely the stall state of the converter 2.

In the case where the operating conditions are such that the power called P is greater than the maximum power Pmax and persists, the operating point oscillates between the two extreme positions defined on the current-voltage output characteristic I (V) of the generator intensity, extreme position defined by the threshold values Imin and Vmin, position denoted A and B in FIG. 2b at points 1 and 2 thereof.

In order to extract an average power from the current generator 1 close to the maximum power Pmax that it is capable of supplying, in accordance with a particularly advantageous characteristic of the regulation system object of the invention, the means 3 detectors with threshold converter 2 dropout are variable threshold dropout detection means. The aforementioned variable thresholds make it possible to change these thresholds Imin and Vmin framing the point of maximum power Pmax towards the coordinates of this point.

For this purpose, the means 3 detectors with variable threshold can operate according to the following process:
- Starting from the operating point with coordinates V0 = Vmin, I0 = I (Vmin) where, according to the usual notation I (Vmin), represents the value of the intensity delivered by the current generator 1, for the voltage V delivered by this equal to Vmin, this point of course corresponds to point A in Figure 2b 1).

The next threshold point can be defined for example by the torque V1, I1, the current intensity value I1 being defined by I1 = k _I I0 and the value V1 corresponding to the voltage value on the current-voltage output characteristic of current generator 1. The successive threshold values can then be defined from the previous threshold value V1, I1, for example by the pairs V2 = k _V .V1 and I2 corresponding to the value of current for the aforementioned voltage value V2 and more generally, by the following pairs:

Of course, the coefficients kI and kV are coefficients strictly less than 1.

- Starting from the operating point with coordinates I0 = Imin, V0 = V (Imin) where according to the usual notation V (Imin) represents the value of the voltage V on the current-voltage output characteristic I (V) of the generator current 1. This point corresponds substantially to point B in Figure 2b at points 1 and 2 thereof.

kI et kV étant définis de même que précédemment.The first threshold value corresponding to the couples V0, I0, can then be followed by a second threshold value corresponding to the torque value V1 = K _V x V0 and I1 corresponding to the intensity of the current delivered by the generator. current for the aforementioned voltage value V1, then by the second torque value V2 and I2 = k _I .I1, where V2 represents the value of the voltage on the current-voltage output characteristic of the current generator 1, for l intensity I2 above. In general, the successive threshold values correspond to the torque values:

kI and kV being defined as above.

As can be seen, the evolution of the threshold values Imin and Vmin, as described above, thus allow convergence of the operating point towards the maximum power point Pmax.

A more detailed description of the point convergence operation towards the point Pmax of maximum power of the characteristic will be given in connection with FIG. 2c.

When the power demand exceeds the power Pmax, under the effect of successive inversions by the switch K in the regulation loop during setbacks triggered by the crossing of the initial thresholds Imin and Vmin, the successive thresholds converge respectively towards I (Pmax ) and V (Pmax).

The converter extracts a power P Pmax but the power supplied P tends towards Pmax. When the power called P is greater than the maximum power Pmax, the voltage delivered by the converter cannot remain close to the set value, except in the case where an auxiliary source provides the necessary additional power.

As shown in FIG. 2c, at each crossing of threshold I _2r , the corresponding voltage V (I _2r ) x kV with kV 1 is used for the next voltage threshold. Similarly, at each crossing of threshold V _2r is retained for the next intensity threshold, the corresponding current I (V _2r ) x kI with kI 1.

Under established conditions, the final thresholds respectively have the value: for the intensity threshold: kI x If
for the voltage threshold: kV x Vf such that
V = f (k _I x If) = Vf and I = f⁻¹ (kV x Vf) = If.

In the case where kI and kV tend towards the value 1, kI x If tends towards I (Pmax) and kV x Vf tends towards V (Pmax) but the convergence is slower.

An embodiment particularly suitable for carrying out the above-mentioned process will be given in connection with FIG. 3a.

In accordance with the above-mentioned figure, the means 3 detectors with a drop-out threshold of the converter 2, the thresholds being variable, comprise directly connected respectively to the means for sampling and measuring the voltage V and the current I, denoted 11, 12, a first and second comparator circuit 31, 32 constituted by a differential amplifier. The negative terminal of comparator 31 is directly connected to the output of the voltage sampling and measurement means V, and the positive terminal of this same comparator is connected at the output of the means 12 for sampling and measuring the voltage V via a first attenuator circuit 310, connected in cascade with a first sampler-blocker circuit 311. Of course, the first attenuator circuit 310 has a coefficient d attenuation kV, less than 1.

The means 3 threshold detectors also comprise a second comparator circuit 32, constituted by a differential amplifier, the negative terminal of which is directly connected to the output of the means 11 for sampling and measuring the intensity I and the positive terminal of which is connected to the output means for sampling and measuring the intensity I, via a second attenuator circuit 320, connected in cascade with a second circuit 321 sampler-blocker. The second attenuator circuit 320 has an attenuation coefficient kI, less than 1.

In addition, as shown in FIG. 3a, the variable threshold detection means 3 comprise a flip-flop 33 of RS type, the input R of which is directly connected to the output of the second comparator 32 and the input of which S is directly connected to the output of the first comparator 31. The output Q of the flip-flop 33 of RS type delivers the logic signal C representative of the off-hook or non-off-hook state of the converter 2, with respect to the aforementioned variable threshold values . The exit Q of the RS type flip-flop is connected directly to the sampling-blocking control input of the first blocker-sampler 311 and the output Q to the sampling-blocking control input of the second blocker-sampler 321. The samplers-blockers 321 and 311 allow each to store alternately a fraction kI of the current I delivered by the current generator 1, when the last voltage threshold V _r is crossed and a fraction kV of the voltage V delivered by the current generator 1 to converter 2, when the last current threshold I _r is crossed. The crossing of the thresholds thus memorized therefore corresponding to variable values in accordance with the previously described variation law is detected by the comparators 31 and 32 which then control the flip-flop RS 33, the latter delivering the logic signal C for command to switch the sign of the error signal amplified. In addition, the variable threshold detection means 3 comprise connected at the output of the blocking samplers 311 and 321, ensuring the connection with the positive input of the first and second comparators 31, 32, a conditional switching circuit 312, 322, receiving on a first input the signal delivered by the corresponding blocking sampler 311 or 321 and on a second input a reference voltage V _r1 , V _r2 representative of the limit threshold value Vmin respectively Imin. Each of the conditional routing circuits 312, 322 ensures the transmission of the largest of the values constituted by the value of the signal delivered by the corresponding blocking sampler or by the reference voltage V _r1 or V _r2 .

Thus, when the power called up by the payload increases and is> Pmax, the last sampled threshold values vary accordingly and the threshold threshold values of voltage V and current I delivered by the intensity generator 1, converge towards the corresponding values of current and voltage of the point of maximum power Pmax, values denoted I (Pmax) and V (pmax) as shown in FIG. 2c.

When the power called P by the payload CU becomes less than the maximum power Pmax, capable of being supplied by the intensity generator 1, the converter 2 is then positioned with equi-probability, on one of the two points of possible operation, noted Ai and Bi in Figure 3b.

A practical embodiment allowing on the one hand the initialization of the threshold values Vmin and Imin and on the other hand to impose an operating point such as the point Ai represented in FIG. 3b will be described in conjunction with FIGS. 4a and 4b.

According to FIG. 4a, for which the references correspond to the conditional switching circuit 312 by way of nonlimiting example, this comprises a Zener diode 3120 delivering the reference voltage V _r1 , representative of the voltage value Vmin or Imin . The Zener diode 3120 is connected on the one hand to a resistor 3121 supplied by a supply voltage source + E and on the other hand, to a first diode 3122 polarized in the passing direction with respect to the power source + E. Diode 3122 is connected to the positive input terminal of comparator 31 charged by a resistor 312 connected in parallel to the positive terminal of comparator 31. A second diode 3124 provides the link between the output of the blocking sampler 311, the terminal positive input of comparator 31. The two diodes 3122, 3124 and the resistor 3123 play the role of an analog OR gate allowing the transmission of the signal with the highest amplitude value.

For reasons of electrical constraints imposed on the components of the entire supply system and of the regulation system object of the invention, it may be desirable to impose one of the two operating points Ai or Bi, such as shown in Figure 3b.

Thus, the point Bi will be chosen if one wishes to limit the current absorbed by the converter 2 to a current IL such as IAi> IL> IBi.

On the contrary, the point Ai will be chosen if we want to limit the input voltage of converter 2, to a voltage VL such that VBi> VL> VAi.

For reasons of limitation of electrical stresses on the components, it may be necessary to impose the operating point when the characteristic I (V) of the generator 1, such as a solar generator, varies greatly. These variations correspond, for example, to situations such as space probe approaching the sun, operating point immediately positioned on the current source part, input current of the converter limited to Imin.

As shown in Figure 4c, the operating point can be located in the "current source" area on the generator if you want to limit the input voltage of the converter to a Vlim value or in the "voltage source" area on the generator if on the contrary one wishes to limit the input current of the converter to a value Ilim.

In order to impose on the operating point located on the "current source" area the passage on the "voltage source" area and in order to avoid that the input current of the converter consumes Ilim, as well as is shown in Figure 4b, the variable threshold detection means 3 further comprises a comparator 323 whose positive terminal is connected to the sampling and intensity measurement means I1 and the negative terminal of which is connected to a reference voltage V _r3 representative of the limit intensity Ilim. The comparator 323 by detection of the overshoot, delivers, by its output connected to the input S of the flip-flop RS33 through an OR gate 314 receiving on a second input the signal delivered by the output of the comparator 31 control which allows to introduce a corresponding inversion in the regulation loop 4, making the initial operating point unstable. At the same time, in order to prevent the intensity threshold of the hook detector possibly preventing the operating point from reaching the "voltage source" zone, a switch 325 controlled by the output of the comparator 323 allows the setting in short circuit of the blocking sampler 321, which makes it possible to enter a zero value on the blocking sampler 321, the intensity threshold can then only be reset to the value Imin, if it does not was already.

In order to impose at the operating point located on the "voltage source" zone the passage over the "current source" zone in order to prevent the input voltage of the converter from exceeding Vlim, the detection means 3 to variable threshold include another comparator 313, the positive terminal of which is connected to the voltage sampling and measurement means and the negative terminal of which is connected to a reference voltage V _r4 representative of the limit voltage Vlim. The comparator 313, on detection of the overshoot, delivers by its output connected to the input R of the flip-flop RS33 via an OR gate 324 receiving on a second input the signal delivered by the output of the comparator 32, a signal control allowing to introduce a corresponding inversion in the regulation loop 4. In addition, in order to avoid that possibly the voltage threshold of the detachment detector prevents the operating point from reaching the "source of current ", a switch 326 controlled by the output of comparator 313 allows the simultaneous short-circuiting of the sampler-blocker 312, which makes it possible to enter a zero value on the sampler-blocker 312, the voltage threshold does not can then be reset only to the value Vmin, if it was not already.

Of course, simultaneous use of the circuits for limiting the intensity and the voltage to the values Ilim and Vlim may be carried out provided that the characteristics I (V) of the generator 1, solar generator on board on satellite for example, is such that: Vlim ≧ VCO OR Ilim ≧ ICC AND AND P ≦ Ilim x V (Ilim) P ≦ Vlim x I (Vlim) as shown in Figures 4d and 4e.

A more particularly advantageous embodiment of the differential amplifier means 40 and the reversing means 42 previously described in connection with FIG. 2a will now be described in conjunction with FIG. 3a previously cited.

In accordance with FIG. 3a above, the differential amplifier means 40 and the reversing means 42 can advantageously be constituted by a first error amplifier 401, the positive input of which is connected to the reference voltage Ur delivered by the voltage source of reference 41 not shown in FIG. 3a. The negative input of the first error amplifier 401 is connected to the means 20 for sampling and measuring the voltage Vc delivered by the converter 2. The output of the first error amplifier 401 delivers a first error signal noted ε 1 .

In addition, a second error amplifier 402 is provided, the negative input of which is connected to the reference voltage Ur and the positive input of which is connected to the means 20 for sampling and measuring the voltage Vc delivered by the converter. 2. The output of the second error amplifier 402 delivers a second error signal ε 2 and the gain of the second error amplifier 402 is identical to the gain of the first error amplifier 401. The second error amplifier 402 delivers therefore, taking into account the preceding indications, an error signal ε2 such that ε 2 = - ε1. The output terminal of the first error amplifier 401 and the output terminal of the second error amplifier 402 are each connected to a common point which is connected to the input terminal of the integrator 43. This connection is made by means of load resistors R and switching transistors T1, T2 mounted as a common transmitter and whose base is connected respectively to the output Q, Q of the RS33 scale. The polarization resistors of the transistors T1 and T2 are noted rb. It will of course be noted that the switch K is thus constituted by the transistors T1, T2. The switching to the opening and vice versa to the aforementioned closing allows the common point of the transistor T1, respectively T2, to deliver an amplified error signal, ε 1, or ε2 with ε = ε1 or ε = - ε1. The aforementioned embodiment therefore makes it possible to obtain, at the level of the output terminal, an amplified error signal inverted or not, ± ε.

The embodiment described above gives all satisfaction. However, when switching from the maximum generator power extraction mode to the output voltage regulation mode, due to the symmetry of the system, the generator operating point is likely to be located either in the generator generator zone. voltage, either in the current generator area at random.

However, it may be desirable when switching from the extraction mode of the maximum power of the generator to the voltage or current regulation mode, that the operating point passes systematically and immediately to the voltage source zone or to the source zone. without waiting for the operating point to reach its limit values Ilim or Ulim, as described in the request previously.

This result can, in accordance with the object of an alternative embodiment of the object of the invention, be achieved by providing inverting means comprising an inverter comprising a first input terminal receiving the amplified error signal, a second input terminal, an output terminal and an inversion control terminal receiving the logic signal representative of the stall or non-stall state of the converter, means generating a reference voltage being directly connected to the second output terminal of the inverter, output terminal of the latter being directly connected to the input of the integrator means for delivering to the latter either the amplified error signal, or, on switching via the logic signal representative of the converter stall state, the reference voltage so as to position the operating point directly on the current source or voltage source zone independently of the value of the input current or of the converter voltage.

The abovementioned embodiment will first be described in conjunction with FIG. 5.

In accordance with the aforementioned figure, the regulation system which is the subject of the invention comprises, as described above, a current generator system coupled to a converter 2 with pulse width modulation.

Likewise, the means 11 and 12 for sampling and measuring the voltage V and the current I delivered by the current generator 1 to the converter 2 are provided, these means delivering a signal representative of the above-mentioned intensity and voltage. Detector means 3 at the dropout threshold of the converter 2 receive the signals representative of the above-mentioned intensity 1 and of the voltage V and deliver a logic signal C representative of the dropout or non-dropout state of the converter 2 with respect to the values threshold.

A regulation loop 4 regulates the width of the pulses delivered by the converter. This loop comprises means 20 for sampling and measuring the voltage VC delivered by the converter 2 to the load CU and amplifier means 40 of the differential amplifier type receiving on a first input the signal delivered by the means 20 for measuring the voltage delivered by the converter and on a second input a reference voltage UR delivering the amplified error signal.

In accordance with the embodiment of FIG. 5, which is the subject of the invention, reversing means 42 are provided, which comprise an actual reverser denoted 042 comprising a first input terminal 420 receiving the amplified error signal, a second terminal input 422, an output terminal 423 and an inversion control terminal 421 receiving the aforementioned logic signal C.

In addition, a generator 424 of reference voltage denoted Uc is directly connected to the second input terminal 422 of the inverter 042. The output terminal 4230 of the inverter 042 is directly connected to the input of the integrating means 43 to deliver to the latter either the amplified error signal ε or, on switching via the logic signal C representative of the stall or non-stall state of the converter 2, the reference voltage Uc so as to position directly the operating point on the current source or voltage source zone independently of the value of the input current or the input voltage of the converter 2.

In FIG. 5, the integrating means 43 and the pulse width modulation means constituted by the comparator 440 and the sawtooth generator 441 provide the same function as the same elements in the other embodiments.

The embodiment, object of the invention, as shown in Figure 5 without limitation, then allows to replace the amplified error signal ε ensuring the operation in voltage regulation on the current source area or vice versa on the voltage source area by a constant control voltage constituted by the reference voltage Uc similar to that delivered by the inverted output of the error amplifier 40 when the converter is operating in maximum power extraction mode. Under these conditions, it is easy to see that, thanks to the constant voltage Uc integrated by the integrator 43, the operating point of the converter is always returned to the corresponding operating point in the voltage source zone or vice versa in the current source zone even if , at this time, the power called by the payload CU becomes less than the maximum power that the generator can provide. The operating point of the converter 2 is thus positioned on the current source zone or on the voltage source zone independently of the value of the input current or of the voltage of the converter.

In general, the reference voltage Uc can be constituted by a DC voltage source of good stability. Its voltage value has a value substantially equal to the value of the amplified error signal ε which it replaces for the operating point corresponding to the maximum power extraction regime so as to impose, on reduction of the power demand, a position of the operating point of the converter and of the generator 1 either in the current source area or in the voltage source area.

In Figure 6, there is shown a particular embodiment corresponding substantially to the embodiment of Figure 3a previously described.

In the aforementioned variant embodiment corresponding to FIG. 6 previously mentioned, it will be noted that the control voltage Uc may in fact correspond to one of the two values Uc1 or Uc2, which are close to the control voltage Uc. It will be understood in this case that the two values Uc1 and Uc2 can then correspond to the choice of operation in the voltage zone respectively of the current zone of the generator 1 as a function of the characteristics of the generator and of those of the chopping converter 2. In this case, and in a nonlimiting manner, a switch 4000 allows a user to switch to ensure the choice between the corresponding control voltages Uc1 or Uc2, the voltage Uc1 having for value the voltage value during the operation in maximum power extraction mode for the amplifier 402 represented in FIG. 6, analogous to the amplifier 401 but of opposite polarity, the voltage Uc2 having reciprocally for value the corresponding voltage for the amplifier 401, the latter being deleted and replaced by the aforementioned amplifier 402 . In fact, the switch 4000 can comprise two parts 4000 A, 4000 B forming a double switch, the second part 4000 B comprising a first and a second input terminal, which are respectively connected to the output of the amplifier 401, 402. The output terminal of the second part 4000 B is connected to the first input terminal of the inverter 042. The simultaneous switching of the two parts 4000 A, 4000 B of the switch 4000 allows the substitution of the amplifier 401 or 402 of the control voltage Uc2 or Uc1.

Note however that in practice, these two voltages are very similar and the embodiment presented in Figure 6 then appears as a non-limiting example. Of course, in FIG. 6, all of the elements bearing the references of the elements of the other embodiments previously described, and in particular of FIG. 3a, perform the same functions.

A simplified embodiment of a regulation system in accordance with the object of the present invention will now be described in conjunction with FIG. 7.

According to the embodiment represented in FIG. 7, this represents a simplification of the embodiment represented in FIG. 6. In this case, the amplified error signal ε is delivered by an amplifier 401 playing the role of comparator with respect to a reference voltage denoted Ur. The comparator 401 is followed by the switching stage denoted 42 and of course playing the role of the reversing means 42 previously described. The switching stage 42 is connected in parallel to the output of the amplifier 401 and is constituted by a transistor T1 mounted as a common emitter and the base of which is connected directly to the output Q of the flip-flop 33 of the means 3 threshold detectors converter stall 2.

According to the embodiment shown in FIG. 7, the reference voltage Uc is generated on switching at its high level from the output Q of the flip-flop 33 by saturation of the above-mentioned transistor T1. This switching then makes it possible to apply a substantially zero reference voltage Uc to the input of the integrating means 43, at the saturation voltage denoted VCEsat near the transistor T1, similar to the error voltage of the amplifier replaced during the mode maximum power extraction.

We have thus described a system for regulating the operating point of a DC power supply comprising a current generator system coupled to a particularly efficient pulse width modulation converter.

The regulation system which is the subject of the invention appears to be particularly well suited to space use for supplying electrical energy to electronic circuits of artificial satellites or aircraft and more particularly to space exploration probes. In this case, due to the near impossibility of intervention in the event of failure and the ignorance of the evolution of the behavior of the solar generator, the intensity generator 1, this regulation electronics makes it possible to guard against operating faults. due to particularly unfavorable operating conditions, unfavorable conditions consisting for example of various degradations, state of penumbra, deflection of the sun, distance from the sun, variation in temperature, or the like. Of course, the configuration of the power supply itself is not limiting, a buffer storage assembly constituted by a battery possibly in series with a discharge regulator which can be connected in parallel on the payload CU, at the output of the converter. The operation of the entire regulation system which is the subject of the invention is of course not modified by the presence of such a buffer storage assembly.

The system for regulating the operating point of a DC power supply object of the invention makes it possible to ensure satisfactory operation even in spite of the modification of the current-voltage characteristics of the solar generator, modification due to aging and / or environmental conditions of the electronic components constituting it.

Claims (12)

1. A system for regulating the operating point of a DC power supply comprising a current generator system (1) coupled to a pulse width modulation converter (2), characterized in that said regulation system comprises:
. means (12,11) for sampling and measuring the voltage (V) and the current (I) delivered by said current generator (1) to said converter (2), said means (11, 12) delivering a representative signal said intensity (I) and said voltage (V),
. means (3) threshold detectors detachment of said converter (2) said means (3) receiving said signals representative of the intensity (I) and the voltage (V) delivered by said intensity generator (1) and delivering a logic signal (C) representative of the off-hook or non-off-hook state of said converter (2) with respect to said threshold values,
. a loop for regulating the pulse width delivered by the converter, said loop comprising:
- means (20) for sampling and measuring the voltage (VC) delivered by said converter (2) to the load (CU),
- differential amplifier means (40) receiving on a first input the signal delivered by said means (20) for measuring the voltage delivered by the converter and on a second input a reference voltage (Ur) and delivering an error signal (ε) amplified,
reversing means (42) comprising an input terminal (420) receiving said amplified error signal and an inversion control terminal (421) receiving said logic signal (C) delivered by said threshold detector means and delivering the inverted or non-inverted error signal (± ε),
- integrating means (43) receiving the inverted or non-inverted error signal (± ε) and delivering an integrated error signal (S),
- Pulse width modulation means (44) comprising a comparator (440) and a sawtooth generator (441), said comparator comprising a first input terminal receiving from said integrator (43) said error signal integrated (S) and a second input terminal receiving the signal delivered by the sawtooth generator (441), said comparator (44) comprising an output terminal delivering a control signal (SCL) of pulse width of the pulse width modulation converter. 2. System according to claim 1, characterized in that said means (3) detectors with a drop threshold of said converter (2) are detectors with a variable threshold release. 3. System according to claim 2, characterized in that said means (3) detectors with drop-out threshold of said converter (2) with variable threshold comprise directly connected respectively to the means for sampling and measuring voltage (V) and current (I) delivered by the current generator to said converter, and receiving respectively said signal representative of the voltage (V) and of the intensity (I) delivered by the current generator to said converter:
- A first comparator circuit (31), constituted by a differential amplifier, the negative terminal of which is directly connected at the output of said voltage sampling and measurement means (V) and the positive terminal of which is connected at the output of said means (12 ) sampling and measuring the voltage (V) by means of a first attenuator circuit (310) of attenuation coefficient (KV) connected in cascade with a first sampler-blocker circuit (311),
- a second comparator circuit (32) consisting of a differential amplifier, the negative terminal of which is directly connected to the output of said means (11) for sampling and measuring the intensity (I) and the positive terminal of which is connected to the output of said means of collection and for measuring the intensity (1) via a second attenuator circuit (320) of attenuation coefficient (KI) connected in cascade with a second circuit (321) sampler-blocker,
a flip-flop (33) of RS type whose input R is directly connected to the output of said second comparator (32) and whose input S is directly connected to the output of said first comparator (31), the output Q or Q of said RS type flip-flop (33) being representative of the off-hook or non-off-hook state of said converter with respect to said threshold values, said output Q or Q of the RS type flip-flop being connected directly to the blocking sampling control input of the first blocker sampler (311) and to the blocking sampling control input of the second blocker sampler (321) respectively. 4. System according to claim 3, characterized in that said first and second sampler-blockers are connected to the input of the comparator (31), respectively 32, by means of a conditional switching circuit (312, 322 ) of voltage value respectively of reference current representative of threshold values (Vmin) or (Imin). 5. System according to claim 4, characterized in that each conditional switching circuit (312,322) of a voltage value of reference current respectively (Vmin, Imin) comprises:
- a Zener diode (3120) delivering a reference voltage (V _r1 ) representative of the voltage value (Vmin) or (Imin), said Zener diode (3120) being connected on the one hand to a resistor (3121) supplied by a supply voltage soruce + E and on the other hand to a first diode (3122) polarized in the passing direction relative to the power source + E, said diode (3122) being connected to the input terminal positive of the comparator (31),
- a second diode (3124) ensuring the connection between the output of the sampler-blocker (311) and the positive input terminal of the comparator (31), the two diodes (3122, 3124) and the resistor (3123) playing the role of an analog OR gate allowing the transmission of the signal with the highest amplitude value. 6. System according to claim 6, characterized in that in order to impose the operating point (I, V) of the converter at one of the points Ai, Bi, intersection of the characteristic (I, V) of the generator and of the consumption power curve P = cste, less than Pmax, this comprises, in order to impose on the operating point situated on the "current source" zone the passage over the "voltage source" zone and in order to limit the input intensity of the converter to a value lower than a limit value Ilim,
a computer (323) whose positive terminal is connected to the sampling and intensity measurement means (11) and whose negative terminal is connected to a reference voltage V _r3 representative of the limit current Ilim,
- an OR gate (314) receiving on a first input the signal delivered by the comparator (31) and on a second input the signal delivered by the comparator (323), which makes it possible to introduce a corresponding inversion in the loop of regulation (4), making the initial operating point unstable. 7. System according to claim 5 or 6, characterized in that, in order to impose at the operating point located on the "voltage source" area the passage over the "current source" area and in order to limit the voltage d input of the converter at a voltage lower than a limit value Vlim, this comprises:
- a comparator (313) whose positive terminal is connected to the voltage sampling and measurement means (20) and whose negative terminal is connected to a reference voltage V _r4 representative of the limit voltage Vlim,
- an OR gate (324) receiving on a first input the signal delivered by the comparator (32) and on a second input the signal delivered by the comparator (313), which makes it possible to introduce a corresponding inversion in the regulation loop (4), making the initial operating point unstable. 8. System according to one of claims 6 or 7, characterized in that it further comprises a switch (325), (326) connected in parallel to the input of the sampler-blocker (321) respectively (311 ), each switch (325, 326) being controlled by the output of the comparator (323) respectively (313) which makes it possible to enter a zero value on the sampler-blocker, the intensity or voltage threshold then being unable be reset only to the value Imin or respectively Vmin. 9. System according to one of the preceding claims, characterized in that said differential amplifier means (40) and said reversing means (42) consist of:
- A first error amplifier (401) whose positive input is connected to said reference voltage (Ur) and whose negative input is connected to said means (20) for sampling and measuring the voltage (Vc) delivered by the converter (2), the output of said first error amplifier (40) delivering a first error signal (ε 1),
- a second error amplifier (402) whose negative input is connected to said reference voltage (Ur) and whose positive input is connected to said means (20) for sampling and measuring the voltage (Vc) delivered by the converter (2), the output of the second error amplifier delivering a second error signal (ε 2) with (ε 2 = - ε1), the output terminal of said first error amplifier (401) and the output terminal of said second error amplifier (402) being connected directly to a common point, which is connected to the input terminal of the integrator 43, the connection to the common point being effected via resistor R and switching transistors T1, T2, mounted as a common transmitter and the base of which is connected respectively to the output Q, Q of the RS 33 flip-flop, switching on opening reciprocally on closing of transistors T1, respectively T2, making it possible to deliver an amplified error signal ε = ε1 or ε = - ε 1. 10. System for regulating the operating point of a DC power supply, according to claim 1, characterized in that said reversing means (42) comprise:
- an inverter (042) comprising a first input terminal (420) receiving said amplified error signal (ε), a second input terminal (422), an output terminal (423) and a control terminal d 'inversion (421) receiving said logic signal (C),
- means (424) generating a reference voltage (Uc) directly connected to the second input terminal of the inverter (042), the output terminal (4230) of the inverter (042) being directly connected at the input of the integrating means (43) for delivering to the latter, either the amplified error signal (ε), or on switching via the logic signal (C), representative of the converter stall state , the reference voltage (Uc) so as to position the operating point directly on the current source or voltage source zone independently of the value of the input current or the voltage. 11. System according to claim 10, characterized in that said reference voltage Uc has a value substantially equal to the value of the amplified error signal (ε) for the operating point corresponding to the power extraction regime. maximum so as to impose, on reduction of the power demanded, a position of the operating point, either in the current source area or in the voltage source area. 12. System according to claim 11, characterized in that said amplified error signal (ε) being delivered by an amplifier (401) playing the role of comparator with respect to a reference voltage (Ur) followed by a stage of switching connected in parallel to the output of the amplifier (401) and constituted by a transistor (T1) mounted as a common emitter, the base of which is connected directly to the output Q of the flip-flop (33), said reference voltage Uc is generated on switching at its high level of the output Q of the flip-flop (33) by saturation of said transistor (T1) so as to apply a substantially zero reference voltage Uc to the saturation voltage at the input of the integrating means (43) VCEsat near the transistor (T1).

Images