The present invention relates to a method for identifying the rotor position of an electrical three-phase machine having a rotor and a stator, the three-phase machine being driven by pulsed clamping voltages in accordance with the pulse width modulation method.
The present invention also relates to a device for controlling a three-phase machine in open and/or closed loop, a controller being adapted and designed for implementing the described method.
Additionally, the present invention relates to a three-phase machine having a stator, a rotor, and a device for the open and/or closed-loop control thereof. In general, the present invention relates to encoderless control of a three-phase machine in open and/or closed-loop, the rotor position or the rotor angle being derived from the rotor position dependency of the differential, respectively local inductances.
Evaluating the identified local inductances in accordance with example embodiments of the present invention with regard to the rotor position optimally eliminates the stability problem of certain conventional methods. The subject matter hereof is not determining local inductances. For this, reference is made to conventional methods that are suited for continuously determining local inductances during operation of the three-phase machine using suitable injection voltages. Due to the increased use of three-phase motors instead of direct-current motors, there is considerable interest in high-quality closed-loop control systems for three-phase motors. With the aid of rotor position encoders, such as rotary pulse encoders or resolvers, dynamic and efficient closed-loop control systems of three-phase machines can be obtained in conjunction with pulse-controlled inverters. Disadvantageous in this context is that using rotary position encoders entails a rise in costs and in cabling outlay, and makes failure more likely.
The rotor position is determined during operation by what are generally referred to as encoderless, rotary encoderless or sensorless methods. The rotor position is determined continuously on the basis of the applied voltages and measured motor currents. A component of the fundamental wave methods is the integration of the voltages induced by the rotation of the rotor. However, it is disadvantageous that these methods fail due to vanishing voltages at low rotational speeds. Injection methods utilize the rotor position-dependent inductances of the machine by evaluating the rotor position-dependent current response to a high-frequency voltage excitation, for example. Generally, the high-frequency voltage excitation is additively superimposed on the fundamental voltage indicator.
The disadvantage associated with conventional injection methods is that they do not use the full information content of the rotor position-dependent local inductance matrix, as only the anisotropic component or even only the direction of the anisotropic component of the entire local inductance matrix is used, for example. Moreover, conventional methods make simplified assumptions about the anisotropy. This easily leads to unstable behavior, as soon as the machine exhibits more complicated anisotropic properties that deviate from the assumption.
The publication, Operating Point Dependent Anisotropies and Assessment for Position-Sensorless Control, European Conference on Power Electronics and Applications, Karlsruhe, Sep. 5th-9th, 2016 by W. Hammel et. al. indicates that the parameters of the local inductance matrix not only depend on the rotor position and the instantaneous torque, but, in particular are also directly influenced by the direction of the fundamental current indicator. For conventional injection-based, rotary encoderless, closed-loop control methods, which are based on simplified assumptions, the result is the condition they formulate for a stable operation with respect to the properties of the anisotropy used for the motors to be operated. If conventional methods are used for motors that do not fulfill this condition, this leads to an unstable operation.
Conventional injection methods can be differentiated by the type of injection. For example, in certain injection methods, an alternating one-dimensional injection voltage is additively superimposed on the fundamental voltage indicator. A simple evaluation based thereon assumes that, in the case of a permanently excited synchronous machine, the orientation of the anisotropy coincides with the direction of the d-axis of the rotor. The alternating injection voltage is selected in parallel to the assumed model d-axis. A correct orientation results in the injection-induced a.c. components in parallel to the injection voltage, and thus the injection is torque-free even at high injection amplitudes. On the other hand, if the assumed model d-axis deviates from the actual d-axis, injection-induced a.c. components result that have an additional component orthogonally to the direction of the injection voltage. As a function of this orthogonal current component, the model angle can be adjusted using the correct preceding sign. Thus, an especially simple manner for adjusting the model angle can be attained as long as an anisotropy having the assumed properties is present. In the case of real machines, however, the anisotropy also depends on the magnitude and direction of the fundamental current indicator and leads to the stability problems mentioned.
Among conventional injection methods, there are those which, per evaluation interval, superimpose injection voltages in different directions on the fundamental voltage indicator.
German Patent Document No. 10 2015 217 986, for example, describes an injection method where the trajectory of the injection voltage indicator tip forms a square. On the basis thereof, a calculation rule, which entails very little computational outlay, is presented to determine the anisotropy as a two-component variable. However, even the method it presents does not resolve the difficulty of possible instability caused by the dependency of the anisotropy on fundamental current, as described by W. Hammel et al. in the publication Operating Point Dependent Anisotropies and Assessment for Position-Sensorless Control, European Conference on Power Electronics and Applications, Karlsruhe, Sep. 5th-9th, 2016. However, in contrast to an injection voltage having an alternating voltage indicator, it is possible to determine the complete differential inductance matrix using this injection scheme.
Example embodiments of the present invention provide an improved method for identifying the rotor position of an electrical three-phase machine that permits a rotor-position identification that is stable and noise-immune in all operating points, for three-phase machines having any type of properties of the entire local inductance matrix.
Example embodiments of the present invention also relate to a corresponding device for controlling a three-phase machine in closed or open loop.
Example embodiments of the present invention are based on the realization that rotor positions may only be optimally identified when all rotor position-dependent parameters of the entire local inductance matrix are used in accordance with the manner described herein. To achieve a stable operation, the dependency of the parameters of the local inductance matrix on the orientation of the fundamental current indicator in the closed-loop control system is utilized along the lines described herein.
Example embodiments of the present invention presuppose that the complete differential inductance matrix is continuously determined by a preceding method. For example, the injection method described in the German Patent Document No. 10 2015 217 986, which is expressly incorporated herein in its entirety by reference thereto, may be used.
In a method for rotary encoderless determination of the rotor position of a three-phase machine, the three-phase machine is fed by a converter is operable with pulse width modulation, a model rotor angle and a model current indicator of the three-phase machine is determined, in closed-loop controlled operation, in particular, a first measured value of a measure of a first local inductance of the machine is determined, in closed-loop controlled operation, in particular, a second measured value of a measure of a second local inductance of the machine is determined, a function, in particular a function table that is especially determined offline, of differentials of the measures assigns values of the model rotor angle and of the model current indicator to function values, an error, in particular angle deviation, of the model rotor angle is determined by at least two weighting factors being determined by at least two weighting factors being determined as function values of the function, in particular function table, as a function of the model rotor angle and of the model current indicator, and a sum of the measured values weighted by the weighting factors is produced, and, to determine the error, another offset value is subtracted from the sum, which is likewise determined as a function of the model rotor angle and the model current indicator, the further offset value is determined by the further offset value being determined as a function value of the function, in particular function table as a function of the model rotor angle and of the model current indicator by the function, in particular the function table, the model rotor angle is adjusted by a control loop controlling the error toward zero.
According to example embodiments, the local admittances may be used as a measure of the local inductances.
According to example embodiments, the function may be determined, in particular set offline, in particular one time in a step preceding the positional determination, thus, in particular prior to the closed-loop controlled operation, so that the weighting factors and the offset value are assigned by the function to the values of the two model variables online, in particular when the position is determined.
According to example embodiments, to determine the function, the local inductances are determined as a function of values of the rotor position and of the current indicator, in particular, these values of the current indicator representing a trajectory.
According to example embodiments, the weighting factors and the offset value are assigned to the model variables as a function of the differential of the local inductances or local admittances that is specific to the rotor position.
According to example embodiments, each of the at least two weighting factors is produced as a quotient of the differential of one of the measures and of the square sum of all of the differentials of the measures.
According to example embodiments, the assignment for the offset value to be subtracted is set to conform there to this weighted sum when the actual rotor angle of the machine conforms to the model angle.
According to example embodiments, the weighting factors are selected such that that measure which has the greatest manufacturing tolerances is provided with a lower weight or is not considered in the weighted sum.
In the case of the device that includes a converter and a three-phase motor, in particular a rotary encoderless three-phase motor, the three-phase motor is fed by a converter, in particular a pulse-controlled inverter, which is suitably designed for implementing a method described herein.
Example embodiments of the present invention are explained in greater detail below with reference to the appended Figures.
The differential inductance matrix describes the relationship between current variations and the corresponding injection voltage uc. This matrix is symmetrical and, therefore, includes three independent parameters.
Conversely, the current rise in response to an applied injection voltage uc is determined by the inverse matrix.
Inverse Y of inductance matrix L is often referred to as the admittance matrix here as well in the following. This is likewise symmetrical and determined by the three parameters Ya, Yb and Yab.
Thus, the relationship between the applied injection voltage uc and the corresponding current rise is expressed as follows:
Using the substitutions (5a)-(5c), the admittance matrix may be reduced as illustrated in (6).
In this reduction, YΣ represents the isotropic component of the admittance matrix. On the other hand, the anisotropic component is a variable having magnitude and direction that is represented in (6) by Cartesian components YΔa and YΔb thereof.
The exemplary embodiment may apply to a permanently excited synchronous machine. For such a machine, the local inductance matrix, respectively the local admittance matrix may be determined in the reduction thereof in accordance with (6) with the aid of a square injection, for example. In German Patent Document No. 10 2015 217 986, isotropic component YΣ may be ascertained from the first component of equation (31) as follows:
This may be simplified to (8), whereby isotropic component YΣ may be determined directly from the measured current rises.
Apart from measurement errors, second component ΔiΣy of equation (31) in German Patent Document No. 10 2015 217 986 is zero.
The anisotropic components YΔa and YΔb are derived from the components of indicator equation (43) in German Patent Document No. 10 2015 217 986 as follows:
Admittance components YΣ, YΔa and YΔb may also be determined using other characteristics of the injection voltage, such as of a rotating injection, for example, as described, for example, in the publication A Comparative Analysis of Pulsating vs. Rotating Indicator Carrier Signal Injection-Based Sensorless Control, Applied Power Electronics Conference and Exposition, Austin, Feb. 24-28, 2008, pp. 879-885 by D. Raca et. al.
The method according to an example embodiment of the present invention for rotor position identification is based on determining the three parameters of the admittance matrix. The implementation of the method is not bound to the selected form, respectively reduction in (6). Rather, any other form of representation of the information contained in the admittance matrix may be used as the basis for this.
In particular, to implement the method, it is possible to acquire any three linear combinations from admittance components Ya, Yb, and Yab, respectively, YΣ, YΔa, and YΔb to the extent that they are mutually linearly independent.
A component hereof is appropriately utilizing the realization that the three parameters YΣ, YΔa and YΔb of the local admittance matrix depend not only on rotor position θr but, as a function of the operating points, also on components id and iq of the instantaneous fundamental current indicator, thus they are influenced by the magnitude and direction thereof.
Y
Σ
=Y
Σ(θr,id,iq) (11)
Y
Δa
=Y
Δa(θr,id,iq) (12)
Y
Δb
=Y
Δb(θr,id,iq) (13)
θr representing the electric angle of the rotor position and id respectively iq the components of the fundamental current indicator.
The following considerations are limited to the base speed range. Here, the machine is typically operated using a torque-generating current on the q-axis, i.e., id=0 or along an MTPA (maximum torque per ampere) trajectory, which indicates a fixed association of the d-current as a function of the q-current. This is described by D. Schröder, for example, in Elektrische Antriebe—Regelung von Antriebssysteme 3rd edition, Berlin, Springer 2009. Thus the machine is operated in accordance with (14) or (15).
i
d=0 (14)
respectively
i
d
=i
d,MTPA(iq) (15)
In selecting the operating points, the converter is hereby limited to two remaining degrees of freedom, namely to electric rotor angle θr and q-current iq, while associated d-current id results from the q-current from a fixed association in accordance with (14) or (15), for example. For operating points in accordance with this selection, the dependency of admittance parameters YΣ, YΔa and YΔb is also reduced to just two independent variables θr and iq:
Y
Σ
=Y
Σ(θr,id(iq),iq)=YΣ(θr,iq) (16)
Y
Δa
=Y
Δa(θr,id(iq),iq)=YΔa(θr,iq) (17)
Y
Δb
=Y
Δb(θr,id(iq),iq)=YΔb(θr,iq) (18)
In the case of rotary encoderless operation of the motor on a converter, deviations also inevitably arise between actual electric rotor angle θr and corresponding model rotor angle θr,mod in the converter. However, even when these ideally turn out to be very small, unstable operation may result in conventional rotary encoderless methods, as described by W. Hammel et. al. in Operating Point Dependent Anisotropies and Assessment for Position-Sensorless Control, European Conference on Power Electronics and Applications, Karlsruhe, Sep. 5th-9th, 2016.
To orient the fundamental current indicator to be applied, the converter will only be able to revert to model rotor angle θr,mod. If this does not conform to actual electric rotor angle θr, the result is that the actual d- and q-current components no longer conform with the corresponding model variables. The d- and q-current components id and iq actually flowing in the motor are dependent at this stage on the model variables in converter id,mod and iq,mod as well as on the error of rotor angle model {tilde over (θ)}r, as follows:
i
d
=i
d,mod·cos({acute over (θ)}r)−iq,mod·sin({tilde over (θ)}r) (19)
i
d
=i
d,mod·cos({acute over (θ)}r)+iq,mod·sin({tilde over (θ)}r) (20)
{tilde over (θ)}r=θr,mod−θr (21)
If there is an error of model rotor angle {tilde over (θ)}r, the assignment according to (14), respectively (15) between the actual q- and d-current components does not take place, rather model d-current id,mod is generated as a function of the model q-current iq,mod:
i
d,mod=0 (22)
respectively
i
d,mod
=i
d,MTPA(iq,mod) (23)
Since, in accordance with (11)-(13), the admittance parameters are dependent on actual d- and q-currents id and iq, in comparison to (16)-(18), they will have an additional dependency on the error of model rotor angle {tilde over (θ)}r respectively on model rotor angle θr,mod:
Y
Σ
=Y
Σ(θr,iq,mod,{tilde over (θ)}r) (24)
Y
Δa
=Y
Δa(θr,iq,mod,{tilde over (θ)}r) (25)
Y
Δb
=Y
Δb(θr,iq,mod,{tilde over (θ)}r) (26)
respectively
Y
Σ
=Y
Σ(θr,iq,mod,θr,mod) (27)
Y
Δa
=Y
Δa(θr,iq,mod,θr,mod) (28)
Y
Δb
=Y
Δb(θr,iq,mod,θr,mod) (29)
Thus, measurable admittance parameters YΣ, YΔa and YΔb are dependent on the two model variables iq,mod, and θr,mod known in the converter as well as on a further variable, namely actual rotor angle θr unknown in the converter.
Model d-current id,mod is generated from model q-current iq,mod in accordance with selected MTPA characteristic 103 as expressed by equations (22) respectively (23). Actual motor current components id and iq are derived from model current components id,mod and iq,mod by the transformation of model rotor coordinates into actual rotor coordinates 102 in accordance with equations (19) and (20) using phase angle error {tilde over (θ)}r. In accordance with (21), the error of model rotor angle {tilde over (θ)}r is the difference between model rotor angle θr,mod and actual rotor angle θr. Finally, within the three-phase machine, measurable admittance parameters YΣ, YΔa and YΔb are generated as a function of actual current components id and iq as well as of actual rotor position θr in accordance with equations (11)-(13).
Overall, this results in a mapping 100 of the model variable of q-current iq,mod and of model rotor angle θr,mod as well as of actual rotor angle θr onto measurable admittance parameters YΣ, YΔa and YΔb, in accordance with equations (27)-(29).
What is decisive is the realization that an error of the model rotor angle does, in fact, influence the admittance parameters, but they may nevertheless be measured, unaltered, using an injection process.
Based on this realization, it is fundamentally possible to use the measured admittance parameters to identify the rotor position. This would be very simple to realize if one of the relationships (27)-(29) could be uniquely solved for rotor angle θr in a reversible process. Generally, however, this is not the case for any of the three variables.
In any case, however, it is necessary to know the dependencies of the admittance parameters on the operating point in accordance with (11)-(13). These may be ascertained, for example, by a preceding offline measurement, it being possible for measurement devices to also be used to determine the rotor position. However, there is no need for this to be determined over the entire d-q current plane to realize the method hereof. If the machine is operated on a current trajectory in accordance with (22), respectively (23), and it is also assumed that the phase angle errors occurring during operation remain small, it suffices to determine the admittance parameters on the current trajectory and in the vicinity thereof.
In accordance with example embodiments of the present invention, the stability problem described by W. Hammel et al. in Operating Point Dependent Anisotropies and Assessment for Position-Sensorless Control, European Conference on Power Electronics and Applications, Karlsruhe, Sep. 5th-9th, 2016 is overcome by a converter internal error signal δF initially being generated from variables θr,mod and iq,mod, and which are available to the converter, as well as from measured admittance parameters YΣ, YΔa and YΔb, whereby this error signal itself again depends only on model q-current iq,mod and model rotor angle θr,mod as well as on unknown rotor angle θr:
δF=δF(θr,iq,mod,θr,mod) (30)
In accordance with example embodiments of the present invention, this signal is generated to represent a measure of the deviation of model rotor angle θr,mod from actual rotor angle θr, and this signal is fed to a controller which adjusts model angle θr,mod to the actual rotor angle. This may be accomplished by a simple PLL control loop, for example. Alternatively, error signal δF may be used as a correction intervention in a fundamental wave model, which may thereby also be used in the low speed range and at standstill.
In accordance with example embodiments of the present invention, error signal δF is generated in accordance with
F=G
Σ
·Y
Σ
+G
Δa
·Y
Δa
+G
Δb
·Y
Δb (31)
A quantity F0 is subtracted from this composite signal F, resulting in error signal δF:
δF=F−F0 (32)
Weights GΣ, GΔa and GΔb as well as quantity F0 are typically not constants, but rather operating point-dependent values. Significant thereby is that there is no need to use actual operating point θr, id and iq to determine these quantities. Rather, the use of the possibly faulty model operating point θr,mod and iq,mod leads nevertheless in the result to a stable operation and, in fact, even in the case of a non-vanishing phase angle error.
Thus, variables GΣ, GΔa, GΔb and F0 are general functions of the model variables:
G
Σ
=G
Σ(iq,mod,θr,mod) (33)
G
Δa
=G
Δa(iq,mod,θr,mod) (34)
G
Δb
=G
Δb(iq,mod,θr,mod) (35)
F
0
=F
0(iq,mod,θr,mod) (36)
As a function of the form of these functions GΣ, GΔa, GΔb and F0, a tabular or functional mapping or a combination of both is practical for the storing or calculation thereof in the converter. The following assumes a tabularly stored dependency of values GΣ, GΔa, GΔb and F0 on the model operating point.
Thus it follows for error signal δF, which is dependent on model variables iq,mod and θr,mod as well as on actual rotor angle θr, that:
δF=Fθ(θr,iq,mod,θr,mod) (37)
It is possible to form functions GΣ, GΔa, GΔb, and F0, and, in fact, solely in dependence upon the model variables such that error signal δF acquires the following properties
and this permits a stable operation because of the properties mentioned.
Thus, in accordance with equation (38), the required property indicates how error signal h is to respond to a change in actual rotor angle θr, namely with a slope 1 in response to a change in actual rotor angle θr, proceeding from corrected operating point θr,mod=θr in the case of set model angle θr,mod.
Additionally, the required property in accordance with equation (39) indicates how error signal δF is to respond to a change in model angle θr,mod, proceeding from adjusted operating point θr,mod=θr in the case of set actual rotor angle θr namely with a slope −1 in response to a change in model angle θr,mod.
Consequently, in the vicinity of corrected operating point θr,mod=θr, error signal δF is proportional to phase angle error {tilde over (θ)}r=θr,mod−θr and is thus suited for adjusting the model angle to the actual motor angle with the aid of a closed-loop control circuit.
Moreover, from required properties (38) and (39) of error signal δF, it follows that the value of error signal δF is constant, for example, as selected in (40), constantly zero for all corrected operating points θr,mod=θr independently of rotor position θr and model q-current iq.
In another step, GΣ, GΔa, GΔb and F0 are formulated at this stage as a function of model variables iq,mod and θr,mod to provide error signal δF in accordance with (31) and (32) with the required properties according to (38)-(40).
This is accomplished by executing GΣ, GΔa, GΔb and F0 as follows:
DΣ, DΔa and DΔb thereby represent the differentials of local admittance parameters YΣ, YΔa and YΔb in accordance with rotor position θr. If the dependencies of local admittance parameters according to (27)-(29) are determined in the above described manner, then differentials DΣ, DΔa and DΔb thereof in accordance with rotor position θr may also be indicated for the corrected operating point:
If the alternative representation according to (24)-(26) is used for the description of the admittance parameters, thus as a function of actual rotor angle θr, of model q-current iq,mod and of error angle {tilde over (θ)}r, the relevant differentials present themselves as follows:
The setting of values GΣ, GΔa, GΔb and F0 selected in accordance with (41)-(44) in conjunction with (45)-(47) or with (48)-(50) not only fulfills conditions (38)-(40) for the error signal, but also yields the best possible signal-to-noise ratio for error signal δF, assuming that the measured values of the admittance parameters YΣ, YΔa, and YΔb generate noise in an uncorrelated and normally distributed manner and with the same standard deviation.
Example embodiments of the present invention also include settings that deviate herefrom. Thus, for example, there may be a deviation from the above setting in the following variants:
In summary, the following steps are to be implemented to execute the method. The following steps are first performed in a preceding offline process:
The subsequent rotary encoderless determination of the rotor position includes the following steps in online operation, as shown in
For the described exemplary embodiment,
Corresponding setpoint d-current id,soll is determined as a function of setpoint q-current iq,soll which is dependent on the desired torque, in accordance with (14) or (15), via MTPA characteristic curve 103, and the setpoint current indicator derived therefrom is fed in model rotor coordinates isollr to setpoint-actual comparison 104. The actual current indicator in model rotor coordinates imodr is formed by inverse transformation 107 from the actual current indicator in stator coordinates is using model rotor angle θr,mod.
Current controller 105 generates the fundamental wave voltage in model rotor coordinates of ufr and thus adjusts actual current indicator imodr to setpoint current indicator Transformation device 106 transforms the fundamental wave voltage from model rotor coordinates into stator coordinates, for which purpose, model rotor angle θr,mod is used, in turn.
Injection voltage ucs is additively superimposed in stator coordinates ufs of on fundamental voltage indicator by summation 108, whereby the entire motor voltage is generated in stator coordinates ums which is amplified by power output stage 109 and fed to machine 111. The injection voltage may also be alternatively added already before transformation 106 into model rotor coordinates.
The currents flowing in the machine are measured by current acquisition 110. Determined herefrom in separation unit 112 are both the fundamental wave current in stator coordinates is as well as, from the high-frequency current components, admittance parameters YΣ, YΔa and YΔb.
Weights GΣ, GΔa and GΔb used for generating weighted sum F are formed via tables, respectively functional mappings 113-115 as a function of model rotor position θr,mod and of model q-current iq,mod
Weights GΣ, GΔa and GΔb used for generating weighted sum F are formed via tables, respectively functional mappings 113-115 as a function of model rotor position θr,mod and of model q-current iq,mod.
Finally, offset F0, which is likewise formed as a function of model rotor position θr,mod and of model q-current iq,mod in the table, respectively functional mapping 116 is subtracted from generated weighted sum F. Error signal δF is ultimately hereby formed and is fed in the present exemplary embodiment to a PLL controller 119. This is usually composed of the series connection of a PI element 117 and of an I-element 118. The PLL controller adjusts model rotor angle θr,mod formed at the output thereof to actual rotor angle θr so that, in the corrected state, it ultimately agrees with the actual rotor angle, and error signal δf then becomes zero. Additionally available at the output of PI element 117 is a model value of electric angular velocity ωmod which may be used, for example, as the actual value for a superimposed speed control loop.
Number | Date | Country | Kind |
---|---|---|---|
10 2017 012 027.7 | Dec 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2018/025313 | 12/11/2018 | WO | 00 |