The invention pertains to a process for determining the position of the rotor, especially the angular position of the rotor, of an electric machine in relation to the stator, wherein a first measurement method is used to determine a first measurement value (α1) of the position.
In addition to the use of sensors, especially Hall sensors, to determine the position of the rotor of electric machines, various other methods for determining these positions based on various physical processes associated with the movement of the rotor are also known. As a function of the position of the rotor, the degree of magnetization of the pole winding cores, for example, changes. The voltage of opposite polarity induced in the pole windings also changes. Both effects can be used to determine the position of the rotor.
The invention is based on the goal of creating a new process of the type indicated above, which makes it possible to determine the position of the rotor with a higher degree of accuracy, in particular an accuracy which remains uniform over a wide range of different operating states of the electric machine.
The inventive process which achieves this goal is characterized in that at least one additional measurement method, i.e., obtaining (α1) is used simultaneously to determine an additional measurement value (α2), and in that an average value (α) of the position of the rotor is determined from these two measurement values (α1, α2).
According to the invention, the position of the rotor can be advantageously determined with greater precision from several measurement values determined in different ways.
In particular, the previously mentioned value (α) can be determined advantageously with the use of weighting factors (A, B), which take into account different ranges of variation of the measurement values (α1, α2). Depending on these ranges, the measurement values (α1, α2) will then be evaluated with the help of larger or smaller weighting factors (A, B).
Variable weighting factors (A, B) are preferably used, which depend on the associated ranges of variation and thus on the operating conditions of the electric machine. Thus the value (α) can be determined with uniform precision under different sets of operating conditions.
In a preferred embodiment of the invention, the average value (α) is found in the following way. First, the values of a periodic function are formed from the measurement values (α1, α2); the measurement values (α1, α2) are inserted into this function as an argument. The function values are multiplied by the weighting factors (A, B) and then added together. Finally, the weighted sum is inserted as an argument into the inverse function of the periodic function to determine the value (α). It is an advantage of this averaging method that discontinuities in the measurement values (α1, α2) have no negative effect.
In a further elaboration of the invention, the weighting factors (A, B) are varied as a function of the magnitude of measurement signals representative of the measurement values (α1, α2). The stronger the measurement signals, the smaller the range of variation of the measurement values.
In an especially preferred embodiment of the invention, the measurement values (α1, α2) for the position of the rotor (7) are determined according to the first and/or at least one additional method without a position sensor on the basis of measurement signals tapped at the phase strands of the electric machine.
These measurement signals are preferably based on the degrees of magnetization of the pole winding cores and/or on voltages induced in the pole windings, both of which vary as a function of the position of the rotor.
In particular, measurement signals based on the varying degrees of magnetization of the pole winding cores are tapped at the star point of the star-wired phase strands.
In the above-mentioned embodiments, the weighting factors (A, B) are varied as a function of, for example, the level of the changes in potential (C) at the star point and on the level of the rotational speed (D) of the rotor.
The invention is explained in greater detail below on the basis of exemplary embodiments and the attached drawings, which relate to these exemplary embodiments:
An electric machine comprises three phase strands 1, 2, 3 wired in star fashion, each with a pole winding comprising an iron core 4, on a stator 6. A rotor 7 of the external type comprises permanent magnets 8 and 9, which, in the exemplary embodiment shown here, form a single magnetic period with a north pole and a south pole.
In another exemplary embodiment, the electric machine could deviate from any of the cited features of the previously described electric machine. The number of phase currents could be greater than or less than 3, and in particular each phase strand could comprise more than one pole winding. The pole windings could be formed on the rotor, especially on an internal rotor. Instead of permanent magnets, it would also be possible to use electromagnets as the field magnets. Instead of wiring the phase strands 1, 2, 3 in star fashion, it would also be possible, alternatively or in addition, to wire them in delta fashion.
An energizing circuit 10 applies the direct voltage of a battery 11 by the pulse width modulation (PWM) method cyclically to the phase strands 1, 2, 3 in pulse-like fashion. The energizing circuit 10 is connected to a central control circuit 12, by which the rotational speed and torque of the electric machine, for example, can be controlled. The control circuit 12 is also connected to ammeters 13-15 for measuring the currents in the phase strands 1, 2, 3. Finally, the central control circuit 12 receives signals from voltmeters 16-19, which detect the potentials at the ends of the phase stands 1, 2, 3 and the potential at the star point 20.
As
The pulses applied as part of the PWM method to the phase strands and/or the separately applied measurement pulses lead, as a result of the different inductances of the phase strands, to characteristic potential jumps at the star point 20, which the voltmeter 19 detects and the control circuit 12 then evaluates, possibly under consideration of the currents determined by the ammeters 13-15.
The control circuit 12 also receives signals from the voltmeters 16-18 for evaluation. All of the received signals are determined and evaluated continuously within very short time intervals, during which the angular position of the rotor experiences practically no change. From the voltages and currents detected continuously in this way with the help of the measuring devices 13-19, it is possible, under consideration of the applied voltage pulses, to calculate the induced voltages of opposite polarity and thus to acquire measurement signals which represent the angular position.
According to
The control circuit 12 also comprises a mixing device 23, which receives the measurement values α1, α2, and which is connected to a weighting device 24, which provides weighting factors A, B. From the two measurement values α1, α2, the mixing device 23 forms an average value α under consideration of the weighting factors A, B. In the exemplary embodiment shown here, the averaging is carried out in such a way that the determined value a satisfies the following equations:
sin α=A sin α1+B sin α2 (1)
cos α=A cos α1+B cos α2 (2).
For the average value α, it follows from (1) and (2) that:
α=arctan [(A sin α1+B sin α2)/(A cosα1+B cos α2)] (3).
The weighting device 24 adjusts the weighting factors A, B as a function of the rotational speed D of the rotor 7 and the amplitude C of the previously mentioned potential jumps at the star point 20.
At large amplitudes C of the potential jumps at the star point, that is, when there are large differences between the inductances of the phase strands 1, 2, 3, and when the rotational speed is low, i.e., when the induced voltages are low, A>B is selected, and thus the measurement value α1 determined by the first method is accentuated. As the speed D increases, the weighting factor B becomes correspondingly larger and A smaller.
Number | Date | Country | Kind |
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10 2010 053 468.4 | Dec 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2011/075284 | 11/23/2011 | WO | 00 | 5/29/2013 |