EP0885481A1

EP0885481A1 - Electronically commutated motor

Info

Publication number: EP0885481A1
Application number: EP97908172A
Authority: EP
Inventors: Benno Doemen; Thomas Von Der Heydt; Fritz Schmider
Original assignee: Papst Motoren GmbH and Co KG
Current assignee: Ebm Papst St Georgen GmbH and Co KG
Priority date: 1996-03-05
Filing date: 1997-03-04
Publication date: 1998-12-23
Also published as: DE19608424A1; WO1997033363A1; DE19780154D2

Abstract

The invention relates to an electronically commutated motor with a permanent magnet rotor and a stator with a rotor position sensor (25) on the stator side which has two exclusive OR signal outputs (48, 50) and supplies an output voltage alternating between said signal outputs (48, 50) while the motor is running, with a phase shift arrangement (R1, C, R2, R1', C', R2') to shift the phase of said alternating output voltage so as to generate a temporally advanced alternating output signal (u56-56') in relation to the alternating output voltage, the angle of advance (ζ) of which increases as the motor revolution speed increases, and with at least one electronic switching component (60, 60') controlled by said alternating output signal (fig. 10b: u56-56') to control a motor stator current.

Description

Electronically commutated motor

The invention relates to an electronically commutated motor with a permanent magnetic rotor and a stator and a rotor position sensor arrangement arranged on the stator side. It also relates to a method for speed-dependent control of the commutation time in such a motor. (One often speaks of the speed-dependent control of the "ignition timing" or "ignition angle", although, for example, no "ignition" takes place when using transistors.)

From DE 39 42 003 A1 it is known to change the commutation time of the winding current according to an empirically determined rule in the acceleration or deceleration phase of an electronically commutated motor. For this purpose, a shift register is used as a variable delay element, with the aid of which the time of commutation can be shifted late, and in which the size of this shift is dependent on a manipulated variable that is supplied to the shift register.

In many cases, however, it is desired that the time of commutation is changed depending on the speed, in such a way that the time of commutation is shifted in the direction of early with increasing speed, because this can improve the efficiency of a motor, especially at high speeds, and consequently reach higher speeds. This is not possible with the delay element according to DE 39 42 003 A1, because it means that the time of commutation can only be shifted in the late direction, which would further impair the efficiency of such a motor at high speeds.

Since many motors run at constant speed during operation, you can help in practice by turning the rotor position sensor (or the Rotor position sensors) from the so-called neutral zone a few degrees earlier, i.e. against the direction of rotation of the motor. However, if this displacement is made too large, this has the disadvantage in some motor types that starting the motor is made more difficult. In addition, it is then often only possible to operate the motor in one direction.

Problems arise particularly with so-called two-pulse motors, in which only two stator current pulses are supplied to the stator winding of the motor per rotor rotation of 360 ° el. (For the concept of a two-pulse motor, see Müller in "asr-digest for applied drive technology", 1977, pages 27 to 31). Such motors cannot start from all impending positions, and if the rotor position sensor is moved from the neutral zone against the direction of rotation, additional problems with the start can arise with such motors.

It is therefore an object of the invention to provide a new electronically commutated motor.

According to the invention, this object is achieved by the subject matter of claim 1. Since the electronic switching element is controlled by the output signal of the phase shifter arrangement and its advance angle increases with increasing speed, the commutation time is shifted more and more early in the course of increasing speed, as a result of which especially at high speeds results in better efficiency. Such a motor is well suited for drives in which the power requirement of the driven device increases with increasing speed, such as e.g. is the case with fans and fans, or for drives with very high speeds.

A particularly simple embodiment of the invention results when the phase shifter arrangement has a series circuit in which a first ohmic resistor is connected in series with a parallel circuit comprising a second ohmic resistor and a capacitor. Such a phase shifter arrangement can therefore be constructed in a very simple manner as a resistance-capacitor arrangement. In a further embodiment, the procedure is preferably such that the ratio of the resistance values from the second ohmic resistor to the first ohmic resistor is approximately 2: 1 and that - in a further preferred embodiment - the capacitor has a capacitance value in the range from 1 to 10 nF. Such capacitors with low capacitance values are not only inexpensive, but also have a long service life, so that there is a high degree of reliability of such a motor, in conjunction with an excellent efficiency at high speeds.

Another solution to the problem arises from the subject matter of claim 18. Here, the fact is exploited that a series connection of a resistor and an inductor at the inductor generates a voltage leading by 90 °, which increases with increasing speed. By means of suitable vectorial addition, a control signal can hereby be generated which leads with increasing speed of the alternating component of the rotor position signal and makes it possible to commutate the motor current earlier with increasing speed. Instead of an inductor in the form of a coil, a so-called synthetic inductor could also be used.

The invention is used in a particularly preferred manner in fans with variable speed. Such fans are used, for example, to ventilate electronic devices. At 20 ° C, such a fan has, for example, a speed of 1500 rpm, and at 60 ° C of 3000 rpm, and in the intermediate ranges, the temperature is changed continuously in order to adjust the cooling air quantity continuously to the amount of heat to be removed. When using the present invention, the efficiency of such a fan can be optimized in the entire speed range. Such optimization is possible in the same way with other drives, the speed of which must be variable within relatively large ranges, for example between 30,000 and 80,000 rpm. Here too - with the simplest of means - the efficiency in the range of the operating speeds can be significantly improved by the invention without incurring any noteworthy costs. Further details and advantageous developments of the invention result from the exemplary embodiments described below and shown in the drawing, which are in no way to be understood as a limitation of the invention, and from the remaining claims. It shows:

1 is a schematic representation of an embodiment of a two-pulse electronically commutated motor,

2 shows a longitudinal section through the motor shown only schematically in FIG. 1,

3 shows a detail, seen in the direction of arrow III of FIG. 2,

4 diagrams for explaining FIGS. 1 to 3,

5 shows the electrical circuit of a preferred rotor position sensor,

6 is a diagram for explaining FIG. 5,

7 is a circuit for explaining a preferred embodiment of the invention,

8 to 12 representations for explaining Fig. 7,

13 shows a variant of FIG. 7,

14 is a diagram for explaining FIG. 13,

15 is a diagram for explaining the phase shifter arrangement according to FIGS. 7 and 12, and

16 shows a separate illustration of the voltages of the vector diagram of FIG. 15 which are important for the application.

The following is a two-strand, two-pulse external rotor motor referred to with a cylindrical air gap, since the invention is easy to explain there and also has special advantages. However, it is pointed out that the invention is suitable for all electronically commutated motors. However, it would not be useful or sensible to explain the invention, for example, on a motor with a flat air gap, as shown in DE 2 321 022 C2.

1 to 3 show a typical example of a two-pulse collectorless external rotor motor 10. This has an external rotor 11 with a continuous magnetic ring 11a, the magnetization of which is approximately trapezoidal, i.e. the magnetic flux density in the region of the poles is largely constant, and the regions 12, 13 between these poles, which are often also referred to as pole gaps, although there are usually no gaps in reality, are narrow.

In Fig. 1, the points with practically constant magnetic flux density for the north pole N by hatching and for the south pole S by symbols are indicated to facilitate understanding. The rotor 11 is e.g. formed as a radially magnetized permanent magnetic part made of barium ferrite or a so-called rubber magnet. Fig. 1 shows the rotor 11 in one of its two stable rest positions, which it can assume in the de-energized state. These rest positions are determined by the shape of the air gap and the shape of the magnetization. In operation, the rotor 11 runs in the direction of the arrow 14.

In this example, the stator 15 of the motor 10 is designed as a double-T armature with an upper stator pole 16 and a lower stator pole 17. The two poles each span almost the entire pole arc. They include between them two slots 18 and 19, in which two winding strands 20 and 21 of a two-strand winding are arranged. The connections of the winding strand 20 are denoted by a1 and e1, those of the winding strand 21 by a2 and e2. The windings 20 and 21 have the same number of turns and the same winding sense, ie if a direct current flows from a1 to e1, the same magnetization of the stator 15 results as if the same direct current flows from a2 to e2. Most are the wires of the two turns are wound in parallel, that is in the form of a so-called bifilar winding, which is not shown in FIG. 1.

Rotor position-dependent sensor means 25, here a Hall generator, are arranged in an angular position on the stator 15 which corresponds approximately to the opening of the groove 18 (or alternatively the groove 19), i.e. the so-called neutral zone 29. (The pole gap 12 or 13 is located in one Position in relation to the slot opening 18 or 19, that is to say in relation to the sensor 25, the motor 10 cannot generate electromagnetic torque, ie it has a gap in its electromagnetically generated torque in this rotational position.) Fan blades L can be fastened on the outside of the rotor 11, as indicated schematically in Fig. 1.

The Hall generator 25 is preferably controlled by the stray field of the permanent magnetic rotor 11. Therefore, as shown in FIGS. 2 and 3, it is arranged directly on a printed circuit board 28, preferably in the form of an SMD part, specifically below the lower end of the rotor magnet 11a designated 29, that is to say in its stray flux area, and in one Distance d (Fig. 3) from this. This distance d can e.g. 1, 5 to 3 mm. The inside of the rotor magnet 11a forms an enveloping cylinder C, and it has proven advantageous to arrange the Hall generator in the region of this enveloping cylinder C, e.g. as shown in Fig. 3 somewhat radially outside of this envelope cylinder C, since there the magnetic flux density of the stray flux of the rotor magnet 11a is relatively large.

Alternatively, it would also be possible to arrange the Hall generator 25 radially inside the rotor magnet 11a, for example also at a somewhat greater distance, or preferably such that the rotor magnet has a specially magnetized control track (not shown) for the Hall generator 25. This control track can then have an approximately sinusoidal magnetization, so that the output signal u of the Hall generator 25 (FIG. 6) also becomes approximately sinusoidal. It appears essential that the edges 49 (FIG. 6) of the signal u must not be too steep, and such a flat edge could be generated in a special magnetization track by means of a corresponding magnetization device. However, the solution presented is because of its large size Simplicity preferred.

Fig. 5 shows the electrical circuit of the Hall generator 25. This is preferably a Hall generator with integrated preamplifiers, e.g. type HW101A. The Hall generator 25 is connected to a positive line 42 via a series resistor 40, and to a negative line 46 via a series resistor 44. If the rotor 11, which is symbolically indicated in FIG. 5, rotates, this results between the outputs 48, 50 of the Hall generator 25 the voltage u (amplified by the internal preamplifiers), the course of which is shown in FIG. 6. It has an offset of e.g. 0.7 V, and it has a voltage swing S of e.g. 86 mV. The greater the distance d, the smaller the voltage swing S, but the closer the curve of the voltage u approaches a sinusoidal voltage, while with small values of d the voltage swing S becomes large, but the curve of u more corresponds to a square-wave voltage. In the context of the invention, a square-wave voltage is less suitable than a more sinusoidal (sinusoidal) voltage, and therefore a compromise must be made between the distance d and the voltage swing S.

The air gap 26 over the stator pole 16 and the air gap 27 over the stator pole 17 are formed in a special way in the motor shown as an example. Starting from the groove 18, as seen in the direction of rotation 14, the air gap 26 increases during approximately 10 to 15 ° el. To a first point 30 at which it reaches its maximum. From then on, the air gap 26 decreases over approximately 165 to 170 ° el. Until approximately the opening of the groove 19, where it reaches its minimum value d1. The air gap 27, as shown, has an identical course. This form of air gap, in cooperation with the described type of magnetization of the rotor 11, causes a reluctance torque T _re ι to arise in operation, which is shown in FIG. 4.

The rotor position in which the pole gap 12 lies opposite the Hall generator 25 is assumed to be 0 ° el. in the region of this position, the Hall generator 25 changes its output signal from high to low or from low to high when the rotor 11 rotates. If you turn the rotor 11 into this position 0 ° el. With the motor de-energized, it becomes by the reluctance _torque T _rβ ι effective in the direction of rotation 14 so that the pole gap 12 is approximately opposite the point 30 of the largest air gap. This position is a stable starting position or rest position of the engine and is therefore designated SS1 in FIG. 4. It lies here at approximately 30 ° el., And likewise in this exemplary embodiment there is a second stable starting position or rest position SS2 at approximately 210 ° el., As shown in FIG. 4, ie when the motor 10 is switched off, it rotates automatically in one of these two rest or start positions.

If - with the motor de-energized - the rotor 11, starting from such a rest position, is turned in the direction of the arrow 14, then one has to apply a torque, ie the reluctance torque T _re ι has a braking effect, approximately to the point d1 with the smallest air gap, where T _re ι becomes zero. The rotor 11 can occasionally remain in this position, which is approximately 155 ° el. Or 335 ° el., And this (unstable) position can therefore be referred to as the unstable starting position IS1 or IS2. The engine 10 must also be able to start from these two rotational positions.

If, starting from IS1, the rotor 11 is turned slightly by hand in the direction of the arrow 14, it is _rotated further by a strong driving T _rβ ι to the position SS2. So there is a braking T _rβ between SS1 and IS1 of relatively low amplitude, and between IS1 and SS2 a driving T _rθ ι of high amplitude.

The Hall generator 25 should control the current in the two strands 20 and 21 in such a way that a driving electromagnetic torque T _β ι is generated between 0 ° el. And 180 ° el

0 ° el. And of 180 ° el. Has a gap 32 or 33, and that likewise between 180 and 360 ° el. A driving electromagnetic torque T _e ι is generated, which at 180 and 360 ° el. Has a gap 33 or 34 has. These gaps 32, 33, 34 are filled by the positive part of T _rβ ι. This is therefore indicated by a plus sign.

When starting at one of the points SS1 or SS2, the driving tel generated according to a curve 36 or 36 ", ie when starting from the position SS1, a strong torque T _β ι acts during the hatched area 38 in FIG. 4, which safely accelerates the motor 10 and starts it. The safe start is a This can be explained in such a way that the pole gap 12 (or 13) always looks for the point with the largest air gap 26 or 27, for example the point 30.

Since the Hall generator 25 is here in the neutral zone 29, i.e. on the border between the two stator poles 16 and 17, the commutation takes place approximately in the middle between the unstable starting position IS2 and the stable starting position SS1, or in the middle between the unstable starting position IS1 and the stable starting position SS2, namely at 0 ° el., 180 ° el., 360 ° el. etc. This is favorable for a safe start, especially from the rotating positions IS1 and IS2.

At higher speeds, however, it would be desirable to move the Hall generator 25 a few degrees counter to the direction of rotation 14, e.g. in place 25 '(Fig. 1), since then the efficiency of the engine is better. This is known from Fig. 9 of DE 2 612464 A1 (D80 = DE-202). However, the Hall generator 25 is then in such a position that the commutation takes place in the vicinity of the unstable starting positions IS1 and IS2, so that the motor cannot start safely in unfavorable circumstances.

In the invention, the Hall generator 25 can be arranged in the neutral zone 29, that is to say that the current in the stator is commutated at low speeds when a rotor pole gap 12, 13 passes through the neutral zone 29. On the other hand, in the invention by electronic means it is achieved that the commutation is shifted more and more towards the early direction with increasing speed, that is to say as if the Hall generator 25 would automatically move to position 25 'with increasing speed.

Fig. 7 shows a preferred circuit according to the invention. The current connections of the Hall generator 25 serving as a rotor position sensor are connected to the positive line 42 via the resistor 40 and to the minus line 46 via the resistor 44. The Hall generator 25 is by controlled the magnetic field of the rotor 11, which is why it is shown symbolically next to the Hall generator 25. If the rotor 11 rotates, the voltage u shown in FIG. 6 arises between the two outputs 48, 50 of the Hall generator 25, ie if the output 48 becomes higher, the output 50 becomes lower, and if the output 50 becomes higher the exit 48 lower. These outputs 48, 50 are therefore also referred to as non-equivalent outputs.

The parallel connection of a resistor 52 and a capacitor 54 is connected to the output 48, which here, as also in FIGS. 8 and 9, are additionally denoted by R1 and C. This parallel connection 52, 54 is connected to the negative line 46 via a node 56 and a resistor 58 (R2). The node 56 is connected to the minus input of a comparator 60, the output signal of which controls an npn power transistor 62, which is connected in series with the line 21 of the motor 10 between the positive line 42 and the negative line 46.

As can be seen, the circuit according to FIG. 7 is constructed symmetrically, and therefore the switching elements on the left-hand side of FIG. 7 are identified by the same reference numerals, but with an apostrophe, e.g. 52 'instead of 52 and C instead of C. The transistor 62' is connected in series with the line 20 of the motor 10 between the positive line 42 and the negative line 46. As shown, the strands 20 and 21 are reversed, so that they generate opposite magnetic fields in the stator 15 during operation. (Alternatively, a bridge circuit could also be controlled by the comparators 60, 60 ', and the motor 10 would only need one line in this case.)

The plus input of the comparator 60 is connected to the node 56 ', and conversely the plus input of the comparator 60' is connected to the node 56, ie the two comparators 60, 60 'are each driven with the voltage between the nodes 56 and 56', but with the opposite sign. This voltage usβ-sβ 'corresponds to the addition of the voltages across resistors 58 and 58', cf. Fig. 7. As shown schematically in FIG. 12, this circuit corresponds to a bridge circuit with the four resistors R1, R2, R1 ', R2'. The inputs of both comparators 60, 60 'lie between points 56, 56' of this bridge circuit, that is to say in its diagonal. If 56 becomes more positive than 56 ', the comparator 60 and the voltage uβo (FIGS. 7 and 10c) block it

Output goes high so that transistor 62 (FIG. 7) turns on and strand 21 receives current. If 56 becomes lower than 56 ', the comparator 60' closes and its output goes high, so that the transistor 62 'is switched on and the string 20 receives current.

Very low voltages such as are used here are sufficient to control the comparators 60, 60 '. The effect of the phase shifter arrangement according to FIG. 7 is based on the fact that the alternating voltage U ₅₆ . ₅ 6 _' between the nodes 56, 56', which is shown in Fig. 10b, the alternating voltage u (Fig. 10a) - between the outputs 48 and 50 of the Hall generator 25 - leads, the

Phase shift, which is denoted by φ in Fig. 10b, increases with increasing speed

To explain the mode of operation, reference is made to FIGS. 8 to 11. 8 there is an alternating voltage UH between points 48 and 46 during operation, the frequency of which is e.g. fluctuates between 0 and 200 Hz: at standstill, UH has a frequency of 0 Hz, and at 6000 rpm, for example 200 Hz.

This voltage UH generates a current i in the right-hand phase shifter element R1, C and R2, which is represented (see FIG. 9) as the vectorial sum of the current ii through the resistor R1 and the current \ _∑ through the capacitor C. if h and J ₂ are 90 ° out of phase with each other, and since \ _{2 increases} with increasing speed, the angle α between ii and i increases with increasing speed. The current ii generates a voltage ui across the resistor R1 which is in phase with h. Likewise, the current i in the resistor R2 generates a voltage u ₂ which is in phase with i. The vectorial sum of the voltages ui and U ₂ corresponds to the output voltage UH at the output 48 of the Hall generator 25. Since the angle ß between the voltages ui and UH is smaller than the angle α, there is a phase advance φ (= α - ß) between the Voltage UH and voltage U2 across resistor R2, and this phase advance increases with increasing speed, because with increasing speed i ₂ becomes larger, consequently also the angle α, and thus also the angle φ.

At the start, the current i2 is practically zero, so that there is no phase advance at the start, but only the resistors R1 and R2 are effective, which then act as voltage dividers.

Since the circuit is constructed symmetrically, the left phase shifter element R1 \ C and R2 'effects the same phase shift of the signal at 180 ° out of phase with UH at the output 50 of the Hall generator 25, so that the alternating voltage U56-56' between the nodes 56 and 56 ' (Fig. 10b), which leads the alternating voltage u (Fig. 10a) between the outputs 48 and 50, and more the faster the rotor 11 rotates. Since the phase-shifted voltage U _56-56 'controls the commutation of the motor 10, cf. 10c, the current in the strands 20 and 21 is switched on and off earlier and earlier as the speed increases, which improves the efficiency of the motor 10, while at the same time providing optimal conditions for starting the motor.

FIG. 15 shows the complete vector diagram for FIGS. 7 and 11. The voltages UH and UH ¹ are antivalent, that is to say offset from one another by 180 ° el. That is, by correct polarity, they add to the alternating voltage u, as in FIG shown. The phase shifter arrangement shown in FIG. 7 for phase shifting the alternating voltage u by the angle φ contains the right phase shifter element C, R1, R2 and the left phase shifter element C, R1 ', R2' because of its symmetrical structure. The phase shifted voltage u _{2 is} generated by the right phase shifter element at the resistor R2, and the phase shifted voltage U ₂ > is generated by the left phase shifter element at the resistor R2 '.

Since the resistors R2 and R2 'are connected in series, the voltage U ₅₆ - ₅₆ ¹ arises at them as the sum of U ₂ and u ₂ ', and if the two phase shifter elements are of the same design, the two voltages U2 and U _{2 '} With this special type of addition, the same phase position as shown in FIGS. 15 and 16.

The two phase shifter members C, R1, R2 and C, R1 ', R2' thus together form a phase shifter arrangement, which by adding the

Voltage USQ. ^ - which leads the voltage u by the angle φ in phase, the phase advance φ may have the speed-dependent curve according to FIG. 11.

The following exemplary values are given for the components in FIG. 7:

Motor 10 ... four-pole motor.

Frequency of the signal u _H ... 0 ... 200 Hz (at 0 ... 6000 rpm)

Hall generator 25 ... HW101A

Resistors 52, 52 '... 220 kΩ

Capacitors 54, 54 '... 4 nF

Resistors 58, 58 '... 100 kΩ

Comparators 60, 60 '... LM2903

Transistors 62, 62 '... BDW93

Resistor 40 ... 2 kΩ

Resistance 44 ... 100 Ω Operating voltage ... 39 V

With these values, the course of the advance angle φ over the rotational speed shown in FIG. 11 results, measured in electrical degrees (° el.). By suitably dimensioning the components, this course can be adapted to the needs. This gives a significant improvement in efficiency, and also a very safe start-up for two-pulse motors. It should be pointed out in particular that an electronically commutated motor with this speed-dependent change in the advance angle has an ideal characteristic for driving a fan.

13 and 14 show a variant in which two (equally large) inductors L and L 'are used to generate the phase lead. The circuit largely corresponds to FIG. 7, which is why some of the components are only indicated. The same reference numerals are used for elements that are the same or function the same as in FIG. 7, and these parts are usually not described again. The circuit is also constructed symmetrically here.

A resistor R3 is first connected to the output 48 of the Hall generator 25, which is connected to the negative line 46 via a node 70 and the series connection of an inductor L and a resistor R4. As shown, node 70 is connected to the minus input of comparator 60. Its plus input is connected to the corresponding node 70 'on the left side of the circuit.

Between the output 48 and the negative line 46 there is an alternating voltage UR during operation, that is to say with the motor 10 rotating, as shown in FIG. 8. This generates a current i through the series circuit R3, L and R4. This creates voltages UR ₃ and UR4 at R3 and R4, which are in phase with the current i. A voltage UL arises at the inductance L, which voltage UR3 and UR ₄ by 90 ° leads, as shown in Fig. 14, and this voltage increases with increasing speed.

The vectorial sum of the voltages u _R3 , u _L and u _R4 corresponds to the voltage UR, and the current i lags behind the voltage UR by the angle γ, as shown in FIG. 14.

The vectorial sum of the voltages U | _ and UR ₄ is denoted by 72 in FIG. 14. Between this sum voltage 72 and the current i there is an angle δ which is greater than the angle γ, ie the voltage 72 leads the voltage UR by the angle φ, as shown in FIG. 14, the

Angle φ corresponds to the difference (δ - γ), and this angle φ increases with increasing speed, so that here too the current through the strands 20, 21 (FIGS. 1 and 7) of the motor 10 is switched on and off all the earlier the faster the engine 10 runs.

13, the two comparators 60, 60 'are controlled by the voltage between the nodes 70 and 70', which corresponds to the vectorial sum of the voltages U | _, UR ₄ on the one hand and uu and UR ₄ > on the other hand. This alternating voltage U _70-70 _'leads the alternating voltage between the outputs 48 and 50 of the Hall generator 25 in phase by an angle φ.

Naturally, many other modifications and modifications are possible for the person skilled in the art within the scope of the present invention.

Claims

claims

1. Electronically commutated motor with a permanent magnetic rotor (11) and a stator (15), with a rotor position sensor arrangement (25) arranged on the stator side, which has two antivalent signal outputs (48, 50) and during operation of the motor between these antivalent signal outputs (48, 50) provides an alternating output voltage (FIGS. 5, 6: u) with a phase shifter arrangement (52, 54, 58; 52 ', 54', 58 '; R3, L, R4) used for phase shifting this alternating output voltage (u). for generating an alternating output signal that leads the temporal advance of the alternating output voltage (u) (FIG. 10b: U ₅ 6- ₅ 6 '). whose

Lead angle (φ) increases with increasing motor speed, and with at least one electronic switching element (60, 60 ') controlled by this alternating output signal (FIG. 10b: usβ-sβ) for controlling a stator current of the motor.

2. Motor according to claim 1, in which the rotor position sensor arrangement has a galvanomagnetic sensor (25).

3. Motor according to claim 2, in which the galvanomagnetic sensor (25) is arranged in a region in the vicinity of the rotor magnet (11a), in which region when the rotor magnet (11a) rotates under the action of a magnetic flux from the rotor magnet (11a) alternating rotor position signal generated by the galvanomagnetic sensor (25) has a sinusoidal course.

4. Motor according to claim 3, wherein the galvanomagnetic sensor (25) in a leakage flux region (29) of the rotor magnet (11 a) is arranged.

5. Motor according to one or more of claims 2 to 4, which is designed as an external rotor motor, and in which the galvanomagnetic sensor (25) is arranged in the magnetic flux region of an axial end of the rotor magnet (11a).

6. Motor according to claim 5, in which the galvanomagnetic sensor (25) on the stator side is arranged in an area outside of an enveloping cylinder (C) formed by the inside of the rotor magnet (11a) (FIG. 3).

7. Motor according to one or more of the preceding claims, in which the rotor position sensor arrangement (25) is designed to detect an alternating output voltage (u) assigned to the neutral zone (29) of the stator (15) in order to advance the timing of the alternating output signal (U ₅ 6.56 ') to keep substantially at zero.

8. Motor according to one or more of the preceding claims, in which the rotor position sensor arrangement has a Hall generator (25).

9. Motor according to claim 8, in which the Hall generator (25) is assigned an analog amplifier arrangement for amplifying the Hall signals generated in it.

10. Motor according to one or more of the preceding claims, which is designed in such a way that its stator arrangement per rotor rotation of 360 ° el. At least two stator current pulses are supplied.

11. Motor according to one or more of the preceding claims, in which the electronic switching element controlled by the phase shifter arrangement is designed as a comparator (60, 60 ').

12. Motor according to one or more of the preceding claims, in which when using a rotor position sensor, which supplies two antiphase rotor position signals at two antivalent outputs in operation, a phase shifter element is connected to each of these outputs, and for controlling the currents in at least two phases of the motor Two comparators (60, 60 ') are provided, which are connected in opposite directions between the outputs (56, 56'; 70, 70 ') of these two phase shifter elements.

13. Motor according to claim 12, in which two comparators (60, 60 ') are provided for controlling two phases (20, 21) of the motor, to which the output signals of the two phase shifter elements can be supplied in phase opposition.

14. Motor according to one or more of the preceding claims, in which the phase shifter arrangement has a series circuit in which a first ohmic resistor (R2, R2 ') is connected in series with a parallel circuit comprising a second ohmic resistor (R1, R1') and a capacitor (C, C).

15. Motor according to claim 14, wherein the ratio of the resistance values of the second ohmic resistor (R1, R1 ') to the first ohmic resistor (R2, R2') is approximately 2: 1.

16. The motor of claim 14 or 15, wherein the capacitor (54, 54 ') has a capacitance value in the range of 1 to 10 nF.

17. Motor according to one or more of claims 14 to 16, wherein the potential at the connection (56, 56 ') between the first resistor (R2, R2') and the second resistor (R1, R1 ') an input of the electronic switching element ( 60, 60 ') can be fed.

18. Motor according to one or more of claims 1 to 13, wherein the phase shifter arrangement is a series connection of two Has elements, namely a third resistor (R3) on the one hand and an inductor (L) and a fourth resistor (R4) on the other hand, the time leading output signal (72) at the

Connection point (70) between these two elements can be removed.

19. Electronically commutated motor with a permanent magnetic rotor (11) and a stator (15), with at least one phase shifter element, in order to start from an alternating rotor position signal (u) supplied to the phase shifter element, a control signal that leads the time relative to this (Fig. 10b: u ₅₆ ₅ 6 _' ) to generate, its temporal advance

(φ) increases with increasing speed, and which serves to control the commutation in at least one strand (20, 21) of the motor, and with at least one galvanomagnetic rotor position sensor (25) for generating the alternating rotor position signal (u), which is arranged on the stator side that at the start of the engine a time advance of the control signal (Fig. 10b) is at least almost avoided.

20. Electronically commutated motor with a permanent magnetic rotor (11) and a stator (15), with a rotor position sensor arrangement (25) arranged on the stator side, which, when the motor is operating, has a first alternating output voltage (UR) at a first output (48) and at one second output (50) supplies a second alternating output voltage (UR) in phase opposition to the first alternating output voltage (UR), with a first phase shifter element (52, 54, 58; R3, L, R4) connected to the first output (48) for generating a Compared to the first alternating output voltage (UR), the output signal (UR _V ) leads in time, the lead angle (φ) of which increases with increasing engine speed, with a second one connected to the second output (50) Phase shifter element (52 ', 54', 58 ';R3', L ', R4') for generating an output signal (URV) which leads the time of the second alternating output voltage (UR) and whose lead angle (φ) increases with increasing speed, and with at least one electronic switching element (60, 60 ') controlled by a combination (u *) of the output signals of the two phase shifter elements for controlling the current in at least one branch (20, 21) of the motor.

21. A method for speed-dependent control of the commutation time in an electronically commutated motor which has a rotor and a rotor position sensor which, depending on the rotor position, generates a rotor position signal which contains an alternating component, the frequency of which is proportional to the motor speed, and which motor also has a stator contains at least one winding phase, the current of which is controlled as a function of the rotor position signal, with the following steps: a) starting from the alternating component of the rotor position signal, an alternating alternating voltage is generated by means of an inductive phase shifter element, which leads the alternating component of the rotor position signal and increases with increasing speed; b) using this leading alternating AC voltage, the commutation is controlled, directly or indirectly, in an assigned winding phase of the motor.

22. The method according to claim 21, in which the series connection of two ohmic resistors and an inductor is used as the phase shifter element for generating the leading alternating alternating voltage, and the sum of a voltage across this inductance and a voltage across one of the ohmic resistors for controlling the commutation in the associated Winding strand of the motor is used.

23. The method according to claim 21 or 22, in which a rotor position signal is used, the alternating component of which has edges in the region of the zero crossings (FIG. 6: 49) which deviate from the edge shape of a square-wave voltage.

24. The method according to claim 23, in which a rotor position signal is used which has a sinusoidal profile.

25. Use of a motor according to one or more of claims 1 to 20 for driving a fan.

26. Use of a motor according to one or more of claims 1 to 20 for driving a variable speed fan.