EP3155718A2 - Control loop of a digital control device of a rotary electric machine with excitation of a motor vehicle - Google Patents

Abstract

The invention relates to a control loop (10) which is installed in a voltage regulator of a motor vehicle alternator and controls an output voltage of the latter by adjusting an excitation current of the alternator. The control loop includes, at the input, means for measuring (31) the output voltage by sampling, generating a measurement signal (U_m), error-calculation means (13) generating an error signal (e) equal to a difference between the measurement signal (U_m) and a set value (U_o), means for processing the error signal (e) including an amplifier (14) and generating a control signal (Y_sat) and, at the output, means (35) for generating a control signal (PWM) controlling excitation control means in accordance with the control signal (Y_sat). According to the invention, the processing means also include a phase-advance filter (24).

Description

 CONTROL LOOP OF A DIGITAL REGULATOR DEVICE OF A ROTATING ELECTRIC MACHINE WITH VEHICLE EXCITATION

AUTOMOBILE TECHNICAL FIELD OF THE INVENTION.

 The present invention relates to a control loop of a digital control device of a rotating electric machine with motor vehicle excitation.

 The invention also relates to a digital controller device comprising this control loop, and a corresponding rotating electric machine.

BACKGROUND ART OF THE INVENTION.

 In a manner known per se, a rotating electrical excitation machine is, unlike an electric machine with permanent magnets, capable of producing a motor torque, or of supplying electrical energy, only when its inductor is traversed by a excitation current.

 A common type of rotating electrical excitation machine, widely used in the automotive field for alternator and starter functions, includes a rotating inductor and a multi-winding stator.

 When the machine operates as an alternator, the current generated in the stator windings by the rotating inductor is rectified so as to deliver a DC voltage to the battery of the vehicle.

 This voltage depends on the rotational speed of the inductor, the connected load and the excitation current.

 For automotive applications, the output voltage must be regulated to remain constant regardless of the rotation speed of the alternator and regardless of the battery charge.

 To do this, the output voltage is measured and continuously compared to a setpoint value by a regulator device which controls the excitation current so as to cancel any difference.

The company VALEO ELECTRIC EQUIPMENT MOTOR has already proposed to perform this regulation from sampling measurements using digital techniques, which provide substantial advantages over conventional analog processes, especially in its European patents EP 0 481 862 and EP 0 802 606.

 In the design of a modern regulating device, the slaving of the output voltage to a setpoint is based on the theorization of a proportional (P) or integral proportional (PI) control loop.

 The realization of this loop by the corresponding algorithms makes it possible to design controllers with programmable functionalities, capable of adapting more easily to the specifications of automobile manufacturers, such as that described in the article "An High Voltage CMOS Voltage Regulator for Automotive". and Chassard, L. Labiste, P. Tisserand et al., Design, Automation & Testing in Europe Conference & Exhibition (DATE), 2010, EDAA.

 In the automotive field, several characteristics of the alternator make it possible to evaluate the performance of the alternator, in particular the following characteristics

 - maximum current delivered as a function of the speed of rotation for a given regulation voltage;

 voltage regulation, that is to say the ability of the alternator to generate a voltage corresponding to the setpoint as a function of the connected loads;

 - system stability, ie the phase margin and the gain margin of the system including the regulator, the alternator, a battery and loads.

 However, the inventive entity has observed on systems comprising high power alternators a decrease in the phase and gain margin.

 This decrease can become critical. It appears in fact a poor voltage regulation which results in an "oscillating" voltage or worse, an output voltage of the alternator that can no longer be controlled by the regulator. This lack of control can lead, for example, to an overvoltage; we then speak of an unstable enslaved system.

 According to arbitrary criteria, the phase margin of the open loop transfer (FTBO) function of a slave system must be greater than 45 degrees, and the gain margin must be greater than 13 dB, to consider the system as stable .

But most often, for a system using a very high power alternator (delivering for example a current of 300 A), the respective criteria of phase margin (> 45 °) and gain margin (> 13 dB) can not more be respected for a performance of voltage regulation identical to that of a alternator of lower power (delivering for example a current of 100 A). The system may be unstable.

 A well-known solution to compensate for the increase in alternator gain is to achieve a decrease in the regulator gain.

 Unfortunately, in the case of a proportional type control loop, the performance of the voltage regulation is affected by the change of the regulator gain.

 Indeed, although the stability criteria are improved, the voltage drop of the voltage regulation as a function of the current flow is then increased, and can reach 600 mV, which is considered as a degradation of the performance of the regulation of voltage with respect to a voltage drop of about 200 mV for a 100 A alternator, for example.

 A known solution for limiting the regulation voltage drop when the regulator gain is decreased is the use of an integral part in the control loop.

 The voltage drop can thus be reduced to a value close to 0 mV; however, it is known that the phase margin and the gain margin are slightly affected.

 There is therefore a need for a solution that would increase the phase margin and gain margin of the FTBO of a voltage regulation system associated with a high power alternator while preserving the performance of the voltage regulation .

GENERAL DESCRIPTION OF THE INVENTION

 The object of the present invention is to satisfy this need and is precisely concerned with a control loop of a digital rotary machine control device with motor vehicle excitation.

 This machine is of the type capable of operating as a generator delivering an output voltage adjusted by an excitation current.

 The digital controller device includes excitation current control means and the regulation loop which comprises:

 at the input, measuring means by sampling the output voltage generating a measurement signal;

error calculating means generating an error signal equal to a difference between the measurement signal and a setpoint value; means for processing this error signal generating a regulation signal comprising an amplifier;

 at the output, means for generating a control signal controlling the control means as a function of the regulation signal.

 According to the invention, the regulation loop according to the invention comprises processing means which furthermore comprise a phase advance filter.

 A Z-transfer function of this phase advance filter is preferably of the form:

1 - (1 - 1 /a).Z ^"1

FT (z = - - - -

1 - (1 - 1 /b ⁾ .Z ^"1

where a is a first predetermined coefficient and b is a second predetermined coefficient such that a> b, and a digital output Y _{n +} i of the phase advance filter is related to a digital input X _n of this phase advance filter by a recurrence equation of the form:

Y _{n + 1} = Υ _η Ζ- ^: Y 1 / b + X, X _n Z ^-1 + X _n Z ^-1 1 / a

where a and b are respectively the first and second predetermined coefficients above.

 The phase advance filter in question then comprises means for implementing this recurrence equation.

 Preferably, these implementation means comprise, at the input of the phase-advance filter, a multiplier by a predetermined factor and at the output of a divider by this predetermined factor.

 According to one particular characteristic, the implementation means further comprise an adder and multiplying elements by inverse values of the first and second predetermined coefficients.

 According to another particular characteristic, the phase advance filter is in series with the amplifier.

 According to yet another particular characteristic, the processing means of this control loop further comprise an integrator in parallel with this amplifier and the phase advance filter.

These processing means furthermore advantageously comprise a saturation block generating a disconnection signal controlling a switch disconnecting the integrator from the error calculation means in the event of detection of a saturation state of the regulation signal.

 Preferably, the integrator is a low pass filter.

 According to a particular embodiment, the phase advance filter has a nominal cutoff frequency which is substantially equal to 22 Hz, an open loop transfer function of the digital controller device having a gain margin substantially equal to 22 dB and a phase margin substantially equal to 80 degrees.

 The invention also relates to a digital regulator device for a rotating electrical machine with motor vehicle excitation, of the type capable of operating as a generator, remarkable in that it comprises a regulation loop having the characteristics described above.

 A motor vehicle-type rotating electrical machine of the type capable of operating as a generator comprising this digital regulator device is likewise covered by the invention.

 These few essential specifications will have made obvious to the skilled person the advantages provided by the invention compared to the state of the prior art.

 The detailed specifications of the invention are given in the following description in conjunction with the accompanying drawings. It should be noted that these drawings have no other purpose than to illustrate the text of the description and do not constitute in any way a limitation of the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

 FIG. 1 is a diagrammatic representation of a rotating electrical machine with excitation known from the state of the art, provided with a digital regulator device comprising a regulation loop, and its use on the onboard network of a vehicle automobile.

 Figure 2 is a block diagram of a control loop of the digital controller device shown in Figure 1, a type "proportional integral" known from the state of the art.

 Figure 3 is an analog representation of a type of phase advance filter implemented in the control loop according to the invention.

Figures 4a and 4b show a frequency response of a digital embodiment of the phase advance filter shown in Figure 3 (gain and phase, respectively).

 Figure 5 is a block diagram of a form of digital implementation of a phase advance filter implemented in a preferred embodiment of the control loop according to the invention.

 Figure 6 is a block diagram of a preferred embodiment of the control loop according to the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

 The rotary electrical excitation machine shown diagrammatically in FIG. 1 is, by way of non-limiting example, a three-phase alternator 1 provided with a digital regulator device 2.

The stator 3 of the alternator 1 comprises three windings subjected to the rotating field created by the inductor 4 traversed by an excitation current I _e .

The alternating current produced in the stator 3 is rectified by a rectifying block 5 and filtered by a capacitor 6 so that the alternator 1 delivers a continuous output voltage U _b + to the battery 7 and to the on-board vehicle network 8 supplying loads 9 (a connection by a power cable being shown schematically by a self-L and a resistor R).

The output voltage U _b + of the alternator 1 is kept constant when the load 9 and the speed of rotation Ω vary by means of a regulation loop 1 0 acting on control means 1 1 of the excitation current. from measurements 1 2 by sampling this output voltage U _b +.

 The control means 1 1 of the excitation current I e generally consist of power transistors 1 1 operating in switching and controlled by a rectangular signal PWM variable duty cycle.

 In the most recent generators 1 known from the state of the art, the regulation loop 1 0 is most often an integral proportional control loop equipped with a calculated feedback anti-saturation system of the type shown in FIG. .

The regulation loop 1 0 comprises, at input, measuring means generally constituted by an analog-digital converter for sampling the output voltage U _b + of the alternator 1 and generating a measurement signal U _m which is compared with a value of U ₀ setpoint.

Error calculation means 13 generate with a first operator "Diff_1" an error signal e equal to a difference between the measurement signal U _m and the setpoint value U ₀ .

In the parallel structure shown in FIG. 2, the error signal e is amplified, on the one hand, by a first amplifier 14 having a predetermined proportional gain K _p , and on the other hand, integrated by an integrator 15.

An output voltage S _a of the first amplifier 14 and an output voltage S of the integrator 15 are summed 16 to produce an intermediate control signal Y.

A saturation block 17 makes it possible to adapt the data format of the regulation loop 10 to that of means for generating the output PWM control signal, by supplying a regulation signal Y _sat from the intermediate control signal Y.

 This control loop 10 of a known type further comprises a calculated feedback anti-saturation system 18, the operation of which is as follows:

- Unsaturated mode.

A quantity Y _dif f represents a difference between an error generation before saturation Y and saturation Y _sat performed by a second operator "Diff_2" 19.

When the loop 10 is unsaturated, the quantity Y _d iff is zero and does not disturb the operation of the integral proportional loop 10 (with a second integrating gain amplifier K, in series with the integrator 15 having a first function of shape transfer FT = 1 / s). The anti-saturation system 18 is considered disconnected.

 Mathematically,

IF (Y = Y _its t) THEN ei = e

 where e, is an intermediate error signal at the input of the second amplifier 20 preceding the integrator 15.

- Saturated mode

The magnitude Y _dif f is non-zero in saturated mode.

The variable Y _diff in saturated mode attenuates more or less significantly (according to a saturating gain K _Nm of an additional amplifier 21) the loop error s, generated by the integral part 15, 20 via a difference realized by a third operator «Diff_3

 Mathematically,

IF (Y ≠ Y _sat ) THEN It should be noted that the structure of the type "computed feedback anti-saturation system" 18 has two difference operators ("Diff_2" 19 and "Diff_3" 22) and an amplifier K | _im applied to a pure integrator 15.

 The problem encountered in this type of circuit known from the state of the art is that the use of an integral part 15, 20 in the regulation loop 10 makes it possible to reduce the voltage drop of the regulation when the regulator gain is decreased, but the phase margin and the gain margin are affected.

 In order to solve this problem, the inventive entity has studied the possibility of adding a phase advance filtering in the regulation loop 10 controlling the alternator 1, if it comprises in particular an integral part 15, 20, 23, as will be explained in connection with Figure 6.

 An analog representation of a type of phase advance filter studied is shown in Figure 3.

 The transfer function of this filter in advance is of the form (one chooses R1 = R = R for a simplified computation):

 A very low attenuation of a value of 1/2, ie -6 dB (20 x log 0.5 = -6 dB)

 This attenuation value may be adjusted if lower or higher attenuation is desired depending on the system control by selecting appropriate values of R1 and R2.

 The low frequency gain of this circuit is indeed given by the relation R2 / (R1 + R2).

 It should also be noted that this phase advance filter is divided into two basic filters:

a "derivative" part (mathematical part situated in the numerator) which has a first cut-off frequency f _c i = 1 / 2πτ; - an integral part (mathematical portion in the denominator) which has a second cut-off frequency f _c2 = 1 / πτ higher than the first cutoff frequency f _c i.

In the context of a digital realization 24, it is then possible to have a similar approach to the analogical study by using a z-transfer function of the type:

 For the digital realization of a phase advance filter 24, the first predetermined coefficient a is greater than the second predetermined coefficient b.

FIGS. 4a and 4b show an example of frequency response of such a filter 24 for a = 2048, b = 1024 and a sampling frequency f _e = 100 KHz in

 \ ■ 2 "π- f

using the relation Z (f) = e ^fe .

 The frequency response of the digital phase advance filter 24 is in fact almost similar to that of the analog phase advance filter (same characteristics, a "derivative" part and an "integral" part).

 A form of digital implementation 24 shown in Figure 5 can be given by analyzing a recursion equation derived from the z-transfer function of the form:

Y _n = Y _n Z ^"1 - Y _n Z ^{" 1} 1 / b + X _n - X _n Z ^"1 + X _n Z ^{" 1} 1 / a

 A multiplier 25 by a predetermined factor M at the input makes it possible to increase the accuracy of the calculation of the phase-advance filter 24; the result at the output of the filter 24 is then divided by this predetermined factor M by a divider 26.

 As shown in FIG. 5, the phase advance filter 24 according to the invention is also implemented by means of an adder 27 and multiplication elements 28, 29 by inverse values of the first and second predetermined coefficients a, b.

 With the multiplier 25 and the divider 26, truncation errors generated by these values are minimized.

 In a preferred embodiment of the invention, the different functional blocks of which are shown in FIG. 6, the digital phase advance filter 24 is added in series with the amplifier 14 of the regulation loop 10.

The description of these functional blocks is as follows: input signal 1 2 representing the voltage of the battery 7 or the voltage of the "B +" terminal of the alternator 1;

 - Analogue filtering 30 (anti-aliasing filter, anti-voltage ripple), associated with the analog-digital converter 31 and voltage divider 30 in order to adapt the voltage level for the analog-digital converter 31;

 digital analog converter 31;

error calculation means 1 3 between the measurement signal U _m and the reference value U ₀ ;

digital setpoint 32 generating the desired setpoint value U ₀ ;

 anti-aliasing filter 33 associated with the decimation induced by the generation of the PWM control signal;

- First amplifier 14 of the proportional part of the regulation loop 1 0 (proportional gain K _p adjusted to ensure the stability of the regulator device 2 connected to the alternator 1 connected to the battery 7);

 - adder block 1 6 between the proportional part 14 and the integral part 23;

saturation block 1 7 making it possible to adapt the data format of the regulation loop 1 0 to that of generating means 35 of the PWM control signal between a minimum value Y _m in and a maximum value Y _ma x;

generation means 35 of the PWM control signal (controlling the control means 1 1 of the excitation current I _e of the alternator 1), made by a comparison between a triangular reference signal (also called "sawtooth" signal And the control signal Y _sat from the saturation block 17;

 switch 36 connecting or disconnecting the integral part 23 as a function of a disconnection signal Cmd generated by the saturation block 1 7;

 second amplifier 20 (with an integrating gain K, adjusted to guarantee the stability of the regulator device 2 connected to the alternator 1 connected to the battery 7);

 lowpass filter 34 of very low frequency low-pass cutoff realizing the integral part 23 of the regulation loop 1 0;

 - Cmd disconnection signal of the switch 36 representing the saturation of the control loop 10 generated by the saturation block 1 7;

 PWM control signal controlling the power electronics 1 1 controlling the excitation current the alternator 1;

- phase advance filter 24, (adjusted to guarantee the stability of the regulator assembly connected to the alternator 1 and connected to the battery 7).

This phase advance filter 24 has the essential characteristic of having a significant positive phase on a given frequency band. Its nominal cut-off frequency f _c is adjusted to obtain maximum phase advance in the control loop 10 in order to obtain on the FTBO of the control system a phase margin and a maximum gain margin.

 In the preferred embodiment of the invention, the regulation loop 10 is an integral proportional control loop 14, 23 which furthermore comprises, unlike the control loops known from the technical state (such as that shown on FIG. Figure 2), a conditional detection anti-saturation system 36, for optimizing the return time to the unsaturated mode.

The integral part 23 of the regulation loop 10 comprising the second amplifier 20 and the integrator 34 is connected or disconnected by the saturation block 17 as a function of the saturation state of the regulation signal Y _sat .

 To do this, the saturation block 17 generates a disconnection signal Cmd controlling the switch 36 applying on the input of the second amplifier 20, either the error signal e, or a zero voltage by a grounding 37.

 The implementation of the saturation detection in the saturation block 17 is performed by a digital algorithm that uses the following signals:

 Y: intermediate regulation signal at the input of the saturation block 17;

Ysat: control signal at the output of the saturation block 17;

 Cmd: Disconnect control signal.

 The saturation detection algorithm is:

IF (Y = Y _sat ) THEN Cmd = 0

 Cmd = 1

The operation of this anti-saturation system in the proportional integral control loop is then as follows: - Unsaturated mode

When the disconnection signal Cmd is in a logic zero state, the unsaturated mode is detected. The switch 36 connects the error signal e to the input of the integral part 23 (i.e. with the second integrating gain amplifier K, in series with the low pass filter 34 which performs the function of integration 15). The anti-saturation system is considered disconnected. Mathematically,

IF (Y = Y _sat ) THEN Cmd = 0 and e; = e.

 where e, is the intermediate error signal at the input of the second amplifier 20 preceding the low pass filter 34.

Saturated mode

 When the control signal Cmd is in logic state 1, the saturated mode is detected. The switch 36 then connects the input of the integral part 23 to a zero voltage in order to stop the evolution of the output voltage s, of the integral part 23.

 Mathematically,

IF (Y ≠ Y _sat ) THEN Cmd = 1 and e; = 0.

The output voltage s, of the integral part 23 remains fixed at a constant value during the saturated mode.

Indeed, a pure integration operator performs an operation with respect to the unbounded time [0, + - ∞ [defined by the mathematical function:

 As a result, s is equal to the value of s at the time of switching to saturated mode.

 Now, a pure digital integrator having a first function of transfer of the form (transformed into z):

 vs

 FTO (z)

 -1

 1 - Z

 can be replaced by a low-pass filter 34 digital second function transfer of the form:

 d

 FT1 (Z)

 1 - (1 - d) .Z -1 of identical behavior.

 For example, the plots in the Bode plane, made by the transformation

\ .2π-

Z (f) = e ^fe and parameters c and d with a frequency

2 20 2 20 Samples f _e = 100 KHz, show that above 30 mHz the behavior of the low-pass filter 34 and that of the pure integrator 15 are identical.

The inventive entity has found that the implementation in an alternator 1 300A flow of a digital controller device 2 comprising a control loop 1 0 as described above with a phase advance filter 24 having a frequency a nominal cut-off f _c substantially equal to 22 Hz allowed to obtain a maximum gain margin substantially equal to 22 dB and a maximum phase margin substantially equal to 80 degrees.

 It goes without saying that the above description would apply in similar terms to other models of energizing rotating electrical machines as the three-phase alternator shown in FIG.

 The numerical values indicated correspond to experimental developments and computer simulations carried out by the plaintiff company, and are given only as examples.

 The location of the phase advance filter 24 in the proportional part

14 of the control loop 1 0 is also an example corresponding to a preferred embodiment of the invention; other locations in the regulation loop 1 0 are alternately feasible and would provide similar advantages in terms of phase margins and gain for high power machines 1.

 The invention therefore embraces all the possible variants of embodiment that would remain within the scope defined by the claims below.

Claims

1) Control loop (10) of a digital regulator device (2) of a motor vehicle rotating electrical excitation machine (1) of the type capable of operating as a generator delivering a voltage adjusted output voltage (Ub +) excitation circuit ( _Ie ), said digital regulator device (2) comprising control means (1 1) for said excitation current ( _Ie ) and said regulation loop (10) comprising, as input, measurement means (31) by sampling said output voltage (Ub +) generating a measurement signal (U _m ), error calculating means (13) generating an error signal (e) equal to a difference between said signal measuring (U _m ) and a set value (Uo), processing means (14) of said error signal (e) comprising an amplifier (14) and generating a regulation signal (Y _sa t), and, in output, means (35) for generating a control signal (PWM) controlling said comm means ande (1 1) according to said regulation signal (Y _sa t), characterized in that said processing means (14, 24) further comprise a phase advance filter (24), said phase advance filter ( 24) having a Z-transfer function which is of the form:

where a is a first predetermined coefficient and b is a second predetermined coefficient such that a> b, and said phase advance filter (24) comprises means for implementing a recurrence equation, said recurrence equation having the form :

Y "n ₊ +1 ₁ = Y nz ¹ - Y nz ^_1 i / b + xn - x nr ¹ + X n Z ^_1 l / a

where X and Y are respectively a digital input and a digital output of said phase advance filter (24), and a and b are respectively said first and second predetermined coefficients.

2) a regulation loop (10) of a digital regulator device (2) for a motor vehicle rotating electrical machine (1) according to claim 1, characterized in that said implementation means (25, 26) comprise in inputting said phase-ahead filter (24) a multiplier (25) by a predetermined factor and outputting a divider (26) by said predetermined factor. 3) control loop (10) of a digital regulator device (2) for a motor vehicle rotating electrical machine (1) according to claim 2, characterized in that said means of implementation (25, 26, 27, 28, 29) further comprise an adder (27) and multiplying elements (28, 29) by inverse values of said first and second predetermined coefficients.

4) Regulating loop (10) of a digital regulator device (2) of a motor vehicle rotating electrical machine (1) according to any one of the preceding claims 1 to 3, characterized in that said feed-forward filter phase (24) is in series with said amplifier (14).

5) Control loop (10) of a digital regulator device (2) of a motor vehicle rotating electrical machine (1) according to claim 4, characterized in that said processing means (14, 24, 34) comprise furthermore an integrator (34) in parallel with said amplifier (14) and said phase advance filter (24).

6) Control loop (10) of a digital regulator device (2) of a motor vehicle rotating electrical machine (1) according to claim

5, characterized in that said processing means (14, 17, 24, 34) further comprises a saturation block (17) generating a disconnection signal (Cmd) controlling a switch (36) disconnecting said integrator (34) from said error calculation means (13) when a saturation state of said regulation signal (Y _sat ) is detected.

7) Regulating loop (10) of a digital regulator device (2) of motor vehicle rotating electrical machine (1) according to claim 5 or 6, characterized in that said integrator (34) is a pass filter - low (34).

8) Control loop (10) of a digital regulator device (2) of a motor vehicle rotating electrical excitation machine (1) according to any one of the preceding claims 1 to 7, characterized in that said advance filter of phase (24) has a nominal cut-off frequency (f _c ) which is substantially equal to 22 Hz, an open-loop transfer function of said digital controller device having a gain margin substantially equal to 22 dB and a phase margin substantially equal to 80 degrees.

9) Digital regulator device (2) of a motor vehicle rotating electrical machine (1) of the type of those capable of operating as a generator, characterized in that it comprises a regulation loop (10) according to any one of Claims 1 to 8 above.

10) A motor vehicle rotating electric excitation machine (1) of the type capable of operating as a generator, characterized in that it comprises a digital controller device (2) according to claim 9.