DE4122109A1 - Controlling run=up of electronically commutated DC motor - correcting rotor position before supplying dynamic signal to stator winding - Google Patents

Abstract

Run-up regulation is achieved by blocking the commutator for a given time interval after coupling the DC motor to a current source, during which the static rotor position is determined. The stator winding is then supplied with a current during a second time interval in dependence on the detected rotor position so that the rotor is rotated through a given angle in the same, or in opposition to, the normal direction of rotation before releasing the blocking of the commutator and supplying the stator winding with a dynamic signal controlled by a signal from a rotor position sensor. Pref., a run-up assistance circuit lying between the rotor position sensor (4) and the commutator (5) uses two timing elements (ZG14, ZG15), three analogue switches (6, 7, 8), a memory (13) and a resistance (R2). ADVANTAGE - Reliable motor run-up for each possible rotor position.

Description

The application relates to a method for controlling the Startup of a two-pole electronically commutated DC motor with single-strand stator winding and Permanent magnet rotor, in which the Rotor position sensor against the direction of travel Runner opposite the neutral zone of the stand is staggered.

Such motors are known (EP-A1-3 97 143). If such motors for driving such devices are used, which no when the engine is idle or no significant counter torque at the Generate output shaft, then there is none Difficulty starting the engine because of the Runner due to the reluctance between the stator and Permanent magnet rotor always one at rest Takes a position from which it starts safely.  

However, this is no longer the case if the The motor is at rest on its output shaft Counter moment works. The same difficulty can then occur when the drive has a high momentum owns. In these cases, after the Motors the runner after running out in one any rotational position from which he may not be able to start.

The technical problem underlying the invention is a method of controlling the specify electronically commutated DC motor, which starts the motor safely from everyone conceivable runner position guaranteed.

This technical problem is solved according to the invention following process steps solved:

• a) After switching on the DC motor to one Current source becomes the commutation arrangement for locked for a certain first period of time.
• b) During the first period, the static Runner position determined.
• c) Depending on the static rotor position the stator winding is then during a second period of time in such a way that the Rotor by a certain angle of rotation in or is turned against the direction of rotation.
• d) After the second period, the The commutation arrangement is unlocked and the current supply to the stator winding by the Rotor position sensor supplied dynamic signal controlled.

If the electrically commutated DC motor of the type mentioned at the outset is controlled after being switched on in accordance with the method according to the invention, then it will certainly start up. Advantageous circuit features for carrying out the method are contained in claims 2 and 3. The invention is explained below with reference to the exemplary embodiments shown in FIGS. 1 to 7. It shows

Fig. 1 shows the course of the output at the rotor shaft torque in dependence on the rotational position of the rotor,

Fig. 2 three different rotor positions at the start of the motor from a given rest position,

Fig. 3 three different rotor positions at the start of the motor from a different rest position,

Fig. 4 shows the block diagram of the circuit arrangement for implementing the method according to the invention,

Fig. 5, the timing diagram of the circuit arrangement for carrying out the method in the example of Fig. 3,

Fig. 6 shows the timing diagram of the circuit arrangement when performing the method in the example of FIG. 2 and

Fig. 7 shows a specific embodiment for the circuit arrangement for performing the method.

In Fig. 1 is a diagram gezeiqt showing the stand on the shaft of the double-pole permanent magnet rotor available torque depending on the angle of rotation of the rotor. This torque is impressed on the rotor by the stator winding which is supplied with a constant current. When the pole change of the rotor passes the neutral zone of the stator, the torque is zero. It rises sharply depending on the angle of rotation and has reached the maximum torque at point A, ie after an angle of rotation of approximately 10 °, which remains constant up to point B, ie up to an angle of rotation of approximately 130 °, and then declines linearly. When the pole change of the rotor passes the rotor position sensor, this causes the direction of the current in the stator winding to change, so that the torque curve from 0 to 180 ° is repeated between the angle of rotation from 180 ° to 360 °.

From the diagram in Fig. 1 it can be seen that the maximum torque acts on the rotor when it assumes such a rotational position that the pole change between points A and B, ie approximately between 10 ° and 130 ° or 190 ° and 310 °. If the rotor loaded with a counter torque stops in operation in such a rotary position after being switched off, then it can start safely after the current is switched on again. This is not possible with any other rotary position of the rotor.

A rotor loaded with a counter torque can assume two basic rotational positions from which it cannot start automatically when the motor is switched on again. One rotational position is shown in Fig. 2a and the other rotational position is shown in Fig. 3a.

In the example shown in FIG. 2a, the rotor 1 has stopped in such a rotational position in which the pole change 3 lies in front of the rotor position sensor by a certain angle of rotation. This angle of rotation corresponds approximately to point C in FIG. 1. It can be seen that the rotor does not have the maximum torque when the stator current is switched on at this rotor position. This torque is not sufficient to turn the pole change 3 to point A and thus to ensure that the motor starts.

The operating direction of rotation of the motor is designated by 2 . The above also applies in the event that the rotor 1 assumes a rotational position shifted by 180 °.

According to the method according to the invention, the rotational position of the rotor is determined when the motor is switched on. When this rotational position that in Fig. 2a corresponds, then the stator winding is energized in such a way that the rotor 1 during a certain period of time contrary to the operating direction of rotation 2 is rotated. . After this rotation, it takes the rotational position shown in FIG 2b, that is, the pile change 3 and 3 'occupy the position shown in FIG 2b location. The pole change 3 is approximately at A and the pole change 3 'at A' in Fig. 1. If the motor is switched on in this rotor position, then the maximum torque acts on the rotor 1 and it starts up.

Fig. 2c shows an instantaneous value of the rotor position during operation of the engine.

Another rotational position from which a rotor loaded with a counter torque does not start automatically is shown in FIG. 3a. In this example, the rotor 1 has stopped in a rotational position in which the pole change 3 lies between the rotor position sensor and the neutral zone. In this rotational position, the pole change 3 is approximately at D in FIG. 1. If, when the motor is switched on in accordance with the method according to the invention, the rotational position of the rotor 1 shown in FIG. 3a has been determined, the stator winding is energized in such a way that the rotor is energized during a a certain period of time is rotated in the direction of rotation. Then, the rotor receives the rotational position shown in Figure 3b. A, ie, the polarity reversal 3 is approximately A, and the polarity reversal 3, wherein A. When the commutation is turned on at this rotational position of the rotor, the rotor rotates in the operating direction of rotation further. FIG. 3c also shows a current value of the rotor position during operation of the engine.

The method according to the invention can be carried out with a circuit arrangement, the block diagram of which is shown in FIG. 4. The circuit arrangement is arranged between the Hall switch serving as rotor position sensor 4 and the commutation arrangement 5 with stator winding 17 which is effective during operation of the motor. It contains the decoupling resistor R 2 , the analog switches 6 , 7 and 8 , the inverters 9 and 10 , the AND gates 11 and 12 , the state memory 13 and the timers 14 and 15 . The circuit arrangement also contains the current cutoff comparator 16 .

The mode of operation of the circuit arrangement according to FIG. 4 is explained below with the aid of the pulse diagrams shown in FIGS . 5 and 6. The pulses ZG 14 and ZG 15 also apply unchanged to FIG. 6. The timer 15 has an on time of about 20 ms and the timer 14 has an on time of about 500 ms.

If the motor is switched on at time t = 0, then both timers 14 and 15 are started, but 14 is initially locked, ie until t ₁ of 15 . The timing element 15 blocks the commutation circuit 5 and the analog switch 6 via the inverter 10 . At the same time, the analog switches 7 and 8 are opened. The signal from the rotor position sensor 4 HS or to the state memory 13 can thus be reached. If there is a logic zero at its input R and a logic 1 at its input S, its output Q shows a logic 1. With R = 1 and S = 0, Q = 0.

After the timer 15 has expired, the timer 14 is unlocked. The analog switches 7 and 8 are locked and the analog switch 6 is unlocked. The signal from Q (e.g. HS 1 ) is switched through the analog switch 6 to R 2 . The current limitation is reduced via inverter 10 and current cutoff comparator 16 . The commutation arrangement 5 is released so that the alignment of the rotor can be carried out between t ₁ and t ₂ .

After the timer 14 has expired, ie at time t ₂ , the analog switch 6 is blocked. The current limitation is reset to the original value and the signal of the rotor position sensor 4 is switched directly to the commutation arrangement 5 .

The timing diagrams of FIG. 5 according to the example corresponding to Fig. 3a and 3b. When timer 15 is turned on, it is determined that HS = 0 and = 1. When the timer 14 is turned on at t ₁ , the commutation arrangement 5 is supplied with the pulses HS 1 = 1 and = 0, which cause the stator winding 17 to be energized in such a way that the rotor rotates in the direction of rotation. From t = t ₂ , the signal of the rotor position sensor is again directly connected to the commutation arrangement 5 .

The timing diagrams of FIG. 6 correspond to the embodiment according to Fig. 2a and 2b. When timer 15 is turned on, it is determined that HS = 1 and = 0. If the timer 14 is switched on at t ₁ , the commutation arrangement 5 is supplied with the pulses HS 1 = 0 and HS 1 = 1, which cause the stator winding 17 to be energized in such a way that the rotor 1 rotates counter to the direction of rotation of the operating direction. From t = t ₂ , the signal of the rotor position sensor is again directly connected to the commutation arrangement 5 .

FIG. 7 shows the exemplary embodiment of a practical circuit arrangement with which the block diagram according to FIG. 4 can be implemented. The signal from the rotor position sensor 4 is present at the input 18 . Its supply voltage is at connections 19 and 20 . The operating voltage is at inputs 23 and 24 .

The IC 2 is the commutation arrangement 5 , to the terminals 21 and 22 of which the stator winding 17 is to be connected. The timer 14 consists of IC 1 A, R 3 and C 5 and the timer 15 from T 2, R 21 and C. 4 The functions of the analog switches 6 , 7 and 8 are performed by IC 4 B, IC 4 C and IC 4 A. The state memory 13 is implemented by an RS flip-flop which is formed from IC 3 C and IC 3 D. As AND gates 11 and 12 act D8 and D 2, as an inverter 9 and 10 IC 3 and IC B 3 A as well as 16 Stromabschaltkomparator IC 1 B. The Stromabschaltkomparator 16 is effective only during the alignment operation of the rotor. It then works with a lower threshold (than in normal operation) in order to avoid undesired bouncing (oscillation) of the rotor during the alignment process.

After the alignment process is complete, the threshold is reached of the current cutoff comparator to the normal value reset.

Claims (3)

1. Method for controlling the start-up of a two-pole electronically commutated direct current motor with a single-stranded stator winding and permanent magnet rotor, in which the rotor position sensor is arranged offset against the neutral direction of the stator in the opposite direction of the rotor, characterized by the following method steps:

• a) After switching on the DC motor to a current source, the commutation arrangement is blocked for a certain first time period.
• b) The static rotor position is determined during the first period.
• c) Depending on the static rotor position, the stator winding is then energized for a second period of time in such a way that the rotor is rotated through a certain angle of rotation in or against the direction of rotation.
• d) After the second period of time has elapsed, the blocking of the commutation arrangement is released and the energization of the stator winding is controlled by the dynamic signal supplied by the rotor position sensor.

2. Circuit arrangement for carrying out the method according to claim 1, characterized in that a starting auxiliary circuit is arranged between the rotor position sensor ( 4 ) and the commutation arrangement ( 5 ), which has two timing elements (ZG 14 , ZG 15 ), three analog switches ( 6 , 7 , 8 ), a state memory ( 13 ) and a decoupling resistor (R 2 ). 3. A circuit arrangement according to claim 2, characterized in that between the start-up auxiliary circuit and the commutation arrangement ( 5 ), a current cutoff comparator ( 16 ) activated only during the second period is connected.