DE4222949B4 - Collectorless DC motor - Google Patents

Abstract

brushless DC motor with a stator (10), the at least one stator coil (L1-L4) to Generation of a rotating field, a permanent magnet having rotor (11) and a control device for control the commutation of the rotating field in dependence on the voltage at least one stator coil (L1), wherein the control means a Pulse generator circuit (13) contains, that from the voltage of at least one stator coil (L1) a pulse signal (U4) generated, whose frequency depends on the rotor frequency, wherein the pulse signal (U4) triggers a PLL circuit (17) which provides an output signal (U5) whose frequency is an integer Multiple of the rotor frequency represents and is at least as large as the commutation frequency, and wherein from the output signal (5) of the PLL circuit commutation signals (U10-U13) are obtained, the have fixed phase positions with respect to the rotor rotation, characterized in that the pulse generator circuit (13) outputs the pulse signal (14) from the voltage a single stator coil (21) generated.

Description

The invention relates to a brushless DC motor, and more particularly to a motor in which commutation occurs without sensors responsive to the magnetic field ( US 4,912,378 A. )

brushless DC motors are used especially for high speeds. Usually The motors have two Hall sensors, which are at 90 ° to each other are arranged with respect to the rotor axis and the angular position of the to determine the rotating magnetic field, depending on the commutation switch for the Control stator coils. Such Hall sensors provide additional Components that are sensitive to heat as well as being sensitive to radioactivity and also being damaged by vibrations can.

Out DE 32 09 392 A1 a brushless DC motor is known which manages without magnetic field sensors. The voltages on three stator coils are measured and combined with each other in a microprocessor according to complicated criteria and processed to produce commutation signals. The calculations to be performed by the microprocessor load the microprocessor especially at high speeds. They require a high proportion of the time of the microprocessor, so that it is less available for other tasks.

US 4,912,378 describes a brushless DC motor, in which the electromotive forces or voltages are measured on all stator coils for generating commutation signals and then summed so that only the third harmonic remains, which drives a PLL circuit which generates a pulse train at its output whose frequency is an integer multiple of the frequency of the reference signal. From this pulse frequency, the commutation signals are generated by means of a divider. The tapping of all stator voltages causes a complicated structure of the device.

JP 06-82087 A, Patent Abstracts of Japan describes a position detector, in which, instead of voltages, the currents flowing through the stator coils are measured become. Again, it is necessary to measure the currents of all stator coils.

Of the Invention is based on the object, a brushless DC motor to provide, which has a relatively simple control device and does not require complex signal processing.

The solution This object is achieved according to the invention with the in claim 1 specified characteristics.

at the brushless DC motor according to the invention becomes a pulse signal derived from a single stator coil is, as a reference signal for uses a PLL circuit whose output signal has a frequency, which represents a multiple of the rotor frequency. The PLL circuit generates at its output a pulse train which is higher frequency than that of the rotor frequency dependent pulse signal and has a fixed phase relation to this pulse signal. this means for example, that the Rising edge of every nth pulse of the output signal in phase is at the beginning edge of the rotor frequency dependent pulse signal. The PLL circuit (Phase Lock Loop) is a feedback pulse circuit, which includes a phase comparator and a voltage controlled oscillator, wherein the controlled by the phase comparator oscillator the output signal supplies and through the feedback causes this output signal in phase with the reference input signal of the phase comparator is. Contains according to the invention the feedback loop the PLL circuit has a frequency divider, so not the output signal the oscillator immediately fed back but a signal with a split, lower frequency. Because of that the PLL circuit, the phase angle of the feedback signal to that of the derived from one of the stator coil reference signal tuned , the PLL circuit generates an output signal whose frequency is an integer multiple of the frequency of the reference signal. The pulses of this output signal have equal distances and they are distributed circumferentially to produce the commutation signals for the ones arranged stator coils used. In this way, the commutation signals dependent on generated by the rotor frequency, the reference signal only from a single stator coil is derived.

The Control device is available with a few commercially available components to realize. It works reliably even at high engine speeds fits the Commutation frequency exactly to the respective rotor frequency, so that each the stator coils always exactly in phase energized is to maintain the existing speed.

Of the DC motor according to the invention is suitable for high speeds, from z. B. 860 U / sec, taking into account is that the Commutation frequency is a multiple of the revolution frequency.

at a preferred embodiment According to the invention, the reference signal supplied to the PLL circuit has the frequency of the rotor and the output of the PLL circuit has the commutation frequency, i.e. the rotor frequency multiplied by the number of stator coils. But it is also possible the reference signal e.g. to produce with twice the rotor frequency.

in the The following will be an embodiment with reference to the drawings closer to the invention explained.

It demonstrate:

1 a block diagram of the brushless DC motor and

2 Voltage curves connected to the in 1 designated bodies occur.

According to 1 the brushless DC motor has a rotor 11 with a magnet whose north pole is denoted by N and its south pole by S. The stator 10 In this embodiment, there are four stator coils L1, L2, L3, L4, each extending over about 180 °. The stator coils L1 and L3 together form a ring and the stator coils L2 and L4 together form a ring which is arranged offset by 90 ° to the ring of the stator coils L1, L3. All stator coils L1 to L4 are connected at one end to the positive pole of a DC voltage source 12 while the other end is connected to one of the commutation switches S1, S2, S3, S4. The commutation switches switch the respective coil end to the negative pole of the DC voltage source 12 if they receive a corresponding signal at their control input.

The end of the stator coil L1 connected to the commutation switch S1 is connected to a pulser circuit 13 connected via an output line 16 a pulse signal to the PLL circuit 17 supplies.

The pulser circuit 13 includes a transformer TR whose primary winding between the stator coil L1 and the positive pole of the DC voltage source 12 is switched. The voltage at the primary winding is designated U1. The Senkundärwicklung of the transformer TR is at one end to ground and at the other end to the input of an integrator 14 connected. The input voltage of the integrator is designated U2. The output voltage U3 of the integrator 14 becomes a comparator 15 supplied, which is dependent on the rotor frequency pulse signal U4 via the line 16 to the PLL circuit 17 emits.

In 2 Among other things, the voltage curves U1 to U4 are shown. The voltage U1 at the stator coil L1 has a trapezoidal shape. One revolution period is divided into equal intervals t1 to t4. In the first interval t1 U1 is equal to zero. In the second interval t2, U1 increases linearly, in the third interval t3 U1 maintains its maximum value and in the fourth interval t4 U1 drops linearly. Due to the commutation, a positive voltage spike occurs for a short time between the intervals t1 and t2 20 and between the intervals t3 and t4 a short negative voltage spike 21 ,

The transformer TR removes the DC components (eg voltage fluctuations of the voltage source 12 ) From the voltage U1, so that the voltage U2 to ground has the DC component zero. Instead of the transformer TR, another circuit can be used with which the DC component of the voltage U1 can be eliminated, for example, a differential amplifier. The voltage U2 is from the integrator 14 integrated, creating the voltage U3. Instead of the integrator 14 If another low-pass filter can be used, however, the integrator has the advantage that the amplitude of the voltage U3 is always constant almost independently of the respective rotor frequency. At high rotor frequencies results in a correspondingly high induction voltage, but at the same time the integration period is smaller.

The voltage U3 becomes the input of the comparator 15 supplied, which represents a zero-crossing detector. At each zero crossing of the voltage U3 from plus to minus, a positive edge is created 22 the pulse signal U4. At each zero crossing of the voltage U3 from minus to plus creates a trailing edge 23 of the pulse signal U4, because of the switching hysteresis of the comparator 15 is slightly delayed. In the present embodiment, only the positive leading pulse edges become 22 evaluated. These pulse edges 22 are generated in the period interval of the voltage U1. The pulse signal U4 is a square wave signal in which the positive edges 22 have a defined phase to the rotor position. From this signal, the four switching points of the commutation switches S1 to S4 are formed.

The PLL circuit 17 is a control loop, the pulse signal U4 on line 16 as a reference variable and from this the positive flanks 22 evaluates. The PLL circuit includes a phase comparator 25 whose A input receives the pulse signal U4 and its B input to a feedback line 26 is connected, at which the voltage U7 arises. At the output of the phase comparator 25 arise impulses whose amplitude or duration proportional to the phase shift of the pulses at inputs A and B. This output voltage becomes a PI controller 27 fed from the series circuit of the resistors 28 . 29 and the capacitor 30 consists. The PI controller supplies the input signal for the voltage input IN of the voltage controlled oscillator VCO (Voltage Controlled Oscillator) 31 , The voltage controlled oscillator VCO supplies at its output f a square wave signal U5 whose frequency depends on the voltage at the input IN. The signal U5 is the output signal of the PLL circuit 17 ,

The PLL circuit 17 also includes a frequency divider 33 to which the output signal U5 is supplied. The frequency divider 33 responds to the negative edges of the output signal U5 and generates in the output of the first divider stage a signal U6 and at the output of the second divider stage a signal U7, that of the feedback line 26 is supplied. The signal U6 is generated at half the frequency of the signal U5 and in phase therewith. The signal U7 is generated at a frequency which corresponds to a quarter of the frequency of the output signal U5. In the phase comparator 25 the signal U7 is compared with the signal U4. The PLL circuit 17 controls the phase and frequency of the signal U7 so that this signal is generated in phase with the pulse signal U4. In this way, the output signal U5 of the PLL circuit 17 in phase with the pulse signal U4 on line 16 generated, but with four times the frequency.

The output signal U5 of the PLL circuit 17 becomes a counter 35 fed, which responds to the positive edges of this output signal. The counter 35 is a modulo-four counter whose capacity is equal to the number of stator coils. The counter 35 Accordingly, it has two counter stages, at whose outputs the signals US and U9 arise, the signal U9 has half the frequency of the signal U8. These voltages U8 and U9 become a decode 36 supplied, which has four output lines at which the signals U10, U11, U12 and U13 arise. The signal U10 controls the commutation switch S1, the signal U11 the commutation switch S2, the signal U12 the commutation switch S3 and the signal U13 the commutation switch S4. As 2 shows, the signal U10 is generated in the interval t1, the signal U11 in the interval t2, the signal U12 in the interval t3 and the signal U13 in the interval t4. In this way, each of the stator coils receives 1 to 4 in each interval a pulse in which their voltage would normally be zero. This pulse compensates for the ohmic losses and triggers the stator coils in the correct phase.

The counter 35 has a reset input connected to the output of a NOR gate 37 connected is. The NOR gate 37 receives the output signal U5 at an inverted input and the signals U6 and U7 at other inputs. It generates a signal U14 with a reset pulse 38 when the signals U6 and U7 are zero and when the output signal U5 is "1". This is the case at the beginning of the fourth interval t4. This will be the count of the counter 35 always synchronized clearly to the rotor position.

Out 2 It can be seen that the commutation signals U10 to U13 are generated successively in the intervals t1 to t4. Each of the commutation signals has a duration which corresponds to a quarter of the period of one revolution of the rotor.

Since the stator coil L1 does not induce a voltage U1 until the rotor 11 turns, the circuit works only from a minimum speed. The acceleration to the minimum speed can be generated by means of a start logic, which in the decoder 36 is included or connected externally. During the start-up phase of the engine, the decoder exercises 36 its decoding function is not enough. The start logic forces the commutation switches S1 to S4 in synchronism with increasing frequency to the above-mentioned minimum speed of the motor.

The The invention is not limited to the described use of four stator coils limited and not in the event that all Stators are connected together with their one ends. The invention can also be applied to engines in which the stator coils be switched at both ends.

Of the DC motor according to the invention is suitable especially in vacuum applications, e.g. for turbo pumps. He is radiation and insensitive to shock, vacuum-resistant and needed few cables and cable entries. The tension of a single stator coil is used to control the commutation of all Used stator coils. This will be a complicated and expensive hardware and software dispensable. By abandoning a complex Microcomputer and as a result of using a simple circuit is the risk of interference reduced. High speeds are not guaranteed by a maximum processor speed limited.

Claims (7)

Collectorless DC motor with a stator ( 10 ), which has at least one stator coil (L1-L4) for generating a rotating field, a rotor having a permanent magnet ( 11 ) and a control device for controlling the commutation of the rotating field as a function of the voltage at at least one stator coil (L1), where in the control device a pulse generator circuit ( 13 ), which generates from the voltage of at least one stator coil (L1) a pulse signal (U4) whose frequency is dependent on the rotor frequency, wherein the pulse signal (U4) is a PLL circuit ( 17 ), which provides an output signal (U5) whose frequency is an integer multiple of the rotor frequency and is at least as great as the commutation frequency, and wherein from the output signal (U5) 5 ) of the PLL circuit commutation signals (U10-U13) are obtained which have fixed phase positions with respect to the rotor rotation, characterized in that the pulse generator circuit ( 13 ) the pulse signal ( 14 ) from the voltage of a single stator coil ( 21 ) generated. A collectorless DC motor according to claim 1, characterized in that the pulse generator circuit ( 13 ) means (transformer TR) for removing the DC component from the voltage of the stator coil (L1), a low-pass filter ( 14 ) and a comparator ( 15 ) for detecting the zero crossings of the output signal (U3) of the low-pass filter and for supplying the pulse signal (U4). A collectorless DC motor according to claim 2, characterized in that the low-pass filter ( 14 ) is an integrator. Collectorless DC motor according to one of Claims 1 to 3, characterized in that the PLL circuit ( 17 ) a divider ( 33 ), which returns the output signal (U5) of the PLL circuit after division by an integer number to an input (B) of the PLL circuit. A collectorless DC motor according to one of claims 1 to 4, characterized in that the output signal (U5) of the PLL circuit is a counter ( 35 ) to which a decoder ( 36 ) is connected, which supplies a commutation signal (U10-U13) for each count on a different one of several output lines. A collectorless DC motor according to claim 5, characterized in that the count of the counter ( 35 ) in dependence on the signal level of the stages of the divider ( 33 ) is resettable. A collectorless DC motor according to claim 5, characterized in that the decoder ( 36 ) for starting the rotor ( 11 ) is disabled.