WO2017067800A1

WO2017067800A1 - Releasing a blockage in a pump

Info

Publication number: WO2017067800A1
Application number: PCT/EP2016/074121
Authority: WO
Inventors: Wolfgang Krauth; Volker Hofacker
Original assignee: Robert Bosch Gmbh
Priority date: 2015-10-22
Filing date: 2016-10-10
Publication date: 2017-04-27
Also published as: CN108431418B; EP3365558A1; EP3365558B1; DE102015220657A1; CN108431418A

Abstract

The invention relates to a method for releasing a blockage in a pump, in particular a motor vehicle pump, said pump having a stator and a rotor arranged to rotate in relation to the stator. According to the invention, if the rotor becomes blocked, a rotational vibratory motion of the rotor is generated in order to release the blockage.

Description

Description title

Solution of a blockage in a pump prior art

There are already known methods for solving a blockage in a pump. Pumps are also known, the method for solving a

Use blocking.

In DE 10 2010 043 391 AI a pump is disclosed which with a

Drive unit, a coupling unit and a pump rotor

having formed pump unit. The coupling unit couples the drive unit to the pump rotor. The pump rotor is with a

Displacement axially displaceable stored. The coupling unit is as

Magnetic coupling is formed, wherein the pole arrangement of the magnetic coupling is selected such that when blocking the pump rotor, the pump rotor is moved along the displacement path to the blocking of the

To solve pump rotor. The known pump has to release a blocking additional degrees of freedom of movement, which is why the production of the pump is expensive.

Disclosure of the invention

In contrast, a pump according to the invention with the features of claim 15 and a pump in which a method according to the invention is applied, according to the features of claim 1, a significantly simplified manufacturing and a manufacturing cost reduction. The measures listed in the dependent claims, advantageous refinements and improvements of the main claim features.

It is particularly advantageous that the rotary shaking movement of the rotor is generated by alternately acting a force, or a torque in a first direction of rotation and a further force, or a further torque in a second, opposite to the first direction of rotation, to the rotor , This generation is technically easy to implement.

It is advantageous that the forces, or the torques are generated by energizing the pump. Preferably, the forces, or

Torques generated by the energization of at least one winding. An advantage is to be considered that thus an easy-to-manufacture and cost-effective implementation of a pump is possible.

It is to be considered advantageous that the rotary shaking motion is generated by a pulse-width-modulated energization of the pump, or by a pulse-shaped energization with at least one pulse. Most

Electronics, in particular electrical controls, preferably drive means, usually work with a

pulse width modulated control of the pump, which is why the process can be easily retrofitted.

It is advantageous that pauses are formed between the alternating action of the forces or of the torques. In the breaks, no force acting on the rotor or torque are generated. The breaks in particular allow cooling of the pump.

It is particularly advantageous that the shaking movements are repeated.

Between the Rüttelbewegungen Rüttelpausen be formed in which no force, or no torque is generated on the rotor. The shaking pauses allow a simple way of cooling and a check of the blockage. In particular, can be concluded based on a further rotation of the rotor to a solution of the blockage. Furthermore, it is advantageous that In particular, the Rüttelpausen of shaking movement to vibrate movement longer, whereby the steady heating can be compensated in a simple manner.

It is advantageous that the shaking movement is subdivided into one or more sequences. During a sequence, the strength of the generated forces, or the generated torques and the duration of the generation of the forces or torques are substantially the same.

The advantage is that the pauses within a sequence in which no force acting on the rotor or torque is generated are substantially equal in length.

It is particularly advantageous that between the individual sequences

Sequence pauses are inserted, in which no force acts on the rotor.

It is advantageous that the amount of force, or the torque and the duration of the training of the force, or the torque are varied on the rotor between the individual sequences. Preferably, the amount of force, or the torque and the duration of the training of the force, or the torque on the rotor from sequence to sequence are increased. Increasing increases the likelihood of blocking.

It is to be regarded as advantageous that the number of generated forces, or

Torques that act on the rotor decrease from sequence to sequence.

It is advantageous that a termination of the process takes place upon detection of a rotational movement. The rotational movement can be effected in particular by means of a Hall sensor, in particular the detection of a Hall edge. Also, the rotational movement based on the evaluation of a course of the energization of the pump takes place.

It is to be regarded as advantageous that the monitoring of the rotational movement is carried out continuously. Furthermore, the monitoring of the

Rotational movement in the breaks, in particular the Rüttelpausen or the Sequence pauses are performed between the action of a force on the rotor.

It is particularly advantageous that upon detection of a blockage the energization is interrupted and a Bestromungspause is inserted, which is started after the Bestromungspause with the rotary shaking motion.

Further features of the invention will become apparent from the figures and are explained in more detail in the following description. Show it

Figure 1 is a known from the prior art schematic

Sectional view of a known pump,

FIG. 2 shows a first exemplary embodiment,

FIG. 3 is an exploded view of a pump according to the invention according to FIG. 2,

Figure 4 is an exemplary illustration of the process flow and

Figure 5 shows another embodiment of a pump according to the invention.

FIG. 1 shows a pump 100 which is known from the prior art or from document DE 10 2010 043 391 A1. The pump has a

Drive unit 109, a coupling unit 112 and a pump rotor 113, wherein the pump rotor 113 is part of a pump unit 110. The

Coupling unit 112 couples the pump rotor 113 and the drive unit 109. The pump rotor 113 is mounted axially displaceably with a predefined displacement path d. The coupling unit 112 is designed as a magnetic coupling, wherein the pole arrangement of the magnetic coupling 112 is selected such that upon blocking of the pump rotor 113, the pump rotor 113 along the displacement path to process to release the blocking of the pump rotor 113. FIG. 2 shows a first exemplary embodiment of a pump 1 according to the invention. In particular, a pump 1 according to the invention as

Coolant pump can be used in a motor vehicle. In this case, the pump is preferably arranged within a coolant circuit. The pump 1 comprises a pump housing 10 and a motor housing 30. The pump housing 10 and the motor housing 30 are fixedly connected to each other by means of screws. The pump housing 10 has a first opening 12 and a second opening 14. The first opening 12 forms in particular an inlet and the second opening 14 an outlet for the fluid to be delivered, in particular the cooling liquid for cooling a combustion and / or electric motor in a means of transportation, preferably vehicle.

FIG. 3 shows an exploded view of a pump according to the invention according to FIG. The pump 1 has a pump housing 10 and a motor housing 30. Furthermore, the pump 1 has a sump 20. The sump 20 forms together with the pump housing 10 a

Flow area 22 for the fluid. Between the pump housing 10 and the pump pot 20, a seal 18 is formed. The seal 18 prevents leakage of the fluid from the flow area 22, in particular between the pump pot 20 and the pump housing 10. The seal 18 is formed in particular as an O-ring, preferably as an O-ring seal. The sump 20 has in particular the shape of a pot.

The sump 20 has a flange 26. The flange 26 is the

Pump housing 10 assigned. Preferably, the flange 26 included a groove in which the seal 18 is disposed. The flange 26 also has

Recesses, which connect the pump pot 20 with the

Allow pump housing 10. The recesses are formed in particular as four holes in the edge region of the flange.

The sump 20 further includes a labyrinth 27. The maze 27 prevents the ingress of contaminants, in particular sand particles in the region of the sump 20 in which the rotor is arranged. The labyrinth 27 is in particular circular. It has radially inwardly extending gradations. The gradations are circular and circumferential. By way of example, a ring 29 is formed between the flange 26 and the labyrinth 27. The ring 29 is arranged circumferentially. The ring 29 separates the flange portion 26 from the labyrinth 27. The pump pot 20 has an axis 24. The axis 24 extends in

In the longitudinal direction of the pump pot 20 or in the longitudinal direction of the pump 1. The axis 24 is fixedly connected to the pump pot 20. A rotor 50 is disposed within the flow area 22. The rotor 50 has a

Recess on within the axis 24 is arranged. The rotor 50 is rotatably supported by the axis 24. Furthermore, the rotor 50 comprises magnets 51, which allow cooperation with the stator 40. Depending on the type of pump 1, the rotor 50, at least one magnet, preferably a plurality of magnets. To promote the fluid, the rotor 50 has wings 52. The vanes 52 are formed so that the rotor 50 axially draws the fluid and presses it radially out of the pump housing 10. The suction of the fluid takes place in particular via the pump inlet 12 and the radial squeezing of the fluid takes place via the outlet 14. The wings 24 are on the pump housing 10 axially

facing side of the rotor 50 is arranged. They are arranged in particular in the part of the flow-through region 22 which is formed by the pump housing 10. The part of the rotor 50 that includes the magnets is disposed substantially inside the sump 20. The rotor 52 is rotatably supported by a thrust washer 28 on the axis 24. The

Thrust washer 28 simultaneously forms a plain bearing for the rotor 24. Die

Thrust washer 28 has three feet for attaching the thrust washer to the pump housing 10. The axis 24 extends through a recess 28 of the thrust washer 28. The rotor 50 and the labyrinth 27 prevent penetration of

Dirt in the flow area within the sump 22nd

The flange 26 of the sump 20 is used to connect the motor housing 30 with the pump pot 20. Within the motor housing 30, the stator 40th arranged. The stator 40 consists of two pole plates 42 with axial

against each other bent pole teeth 44. The pole plates 42 are in

fully assembled state at a small tangential distance from one another in such a way nested that on the circumference of the poles, in particular when energized the magnetic poles of the two pole plates 42 of the stator 40 alternate with each other. The pole teeth 44 of the two pole plates 42 are in this case arranged nested in one another such that in the circumferential direction a uniform small distance between the individual pole teeth 44 is formed. Pole or the pole plate teeth 44 are looped by at least one winding 46. Preferably, the pole teeth 44 and the poles of at least two opposite windings 46 are looped.

Around the stator 40, a return ring 48 is formed. The return ring consists of a magnetic field suffering material.

In particular, the return ring 48 consists of a metal sheet, which has been transformed into a circular shape.

To determine the rotor position relative to the stator 40, a Hall sensor 32 is disposed within the motor housing 30. The accuracy of the rotor position determination is dependent on the number of magnets of the rotor 50. The Hall sensor 32 is at a Vorbeidrenrenhen a magnet 51 a

Hall side off. An electronics 60 detects this Hall edge and can close on the speed of the rotor 50 based on the frequency and the distances between the detection of the Hall edges. It can also be concluded whether the rotor 50 rotates.

Between the flange 26 of the pump pot 20 and the motor housing 30, a further sealing element 34 is arranged. The further sealing element 34 prevents ingress of fluid, in particular liquids or gases in the region of the stator 40. In this way, in particular short circuits are prevented by fluids during energization of the stator 40.

On the side of the motor housing 30 facing away from the pump housing 10, the motor housing 30 has an electronics area 36. Within the Electronics area 30, the electronics 60, or the control means, or the control protected by the motor housing 30 and a cover 38 is arranged.

The electronics 60 are used for electrical control of the pump 1. The electronics 60 has in particular a first and a second output stage. Each one

Output stage in series with at least one winding 46 is connected. In particular, the first output stage with the first winding 46 and the second output stage with the second winding 46 are connected in series. The output stages are connected in parallel with each other. The windings are also connected in parallel. Depending on the energization of the first or the second winding

46 acts a force, or a torque on the rotor 50, in particular the magnets 51 of the rotor 50. If, for example, the first winding 46 is energized by means of the first output stage, so a rotational movement is formed in a first direction of rotation. If, however, the second winding is energized by means of the second output stage, a rotational movement of the rotor 50 in a second direction of rotation, wherein the second direction of rotation is opposite to the first direction of rotation, is formed.

The fluid to be pumped may have contaminants. These

Dirt can lead to a sticking of the rotor 50 and the wings 52. In particular, particles in the fluid between the rotor 50 and the labyrinth 27 of the sump 20 may jam and block the pump 1. Furthermore, it is also conceivable that put dirt between the rotor 50 and the pump pot 20 and lead to a blockage of the pump 1.

In particular, the contaminants can prevent a restart of the pump 1. Also, the contamination during operation of the pump 1 can lead to a standstill of the rotor 50 and thus a failure of the pump 1. By a method according to the invention, a solution of a blockage in a pump 1 is made possible. In particular, the method can be used in

Motor vehicle pumps that promote cooling liquids are used. The solution of a blockage is carried out by a rotary shaking 82 of the rotor 50. In the rotary shaking movement 82 of the rotor 50 act alternately forces, or torques in a first direction of rotation and more Forces or other torques in a second, opposite to the first direction of rotation, the rotor 50. The forces or

Torques are generated by energizing the pump 1, in particular

Energization of the windings of the stator 40, generated. By energizing the windings of the stator 40, a magnetic field is generated which attracts or repels the magnets of the rotor 50. As a result of the magnetic field, a force or torque acts on the rotor 50.

In Figure 4, the process flow is exemplified. The course 70 shows when the pump 1 is switched on or off. The course 72 shows the

Generation of a pulse, or the energization, or the generation of a force, or a torque in a first direction of rotation. The curve 74 shows the generation of a pulse, or the energization, or the generation of a force or a torque in a second direction of rotation.

Furthermore, based on the curves 72 and 74, for example, the energization of the windings can be removed by the power amplifiers. When starting the pump 1, the second winding is energized by the second power amplifier. A

corresponding energization is shown as block 80 in FIG. At the beginning, the pump is supplied with current for a normal rotary motion. However, after a defined time, which is so chosen, it is none

Damage to the windings or the pump leads, in particular 300 to 100 oms, preferably 500 ms, detected no rotational movement, so it can be assumed that the pump 1 is blocked. If a blockage is detected, the inventive method according to claim 1 is automatically started.

The method starts after a pause, which is selected so that the heated coils 46 within the stator 40 can cool sufficiently. In particular, the first break lasts between 100ms and 20s, preferably one second. The method starts with the generation of a force or a torque in the opposite direction to the previous start attempt. The pump 1 is controlled by the electronics 60 so that shaking movements of the rotor 50 can form. In particular, the shaking movement can also consist of only a single pulse, in particular Current pulse, force pulse or torque pulse, if this leads in particular to a solution of the blockage. Depends on the

Blocking of the rotor 50, the shaking movement is limited to an alternating action of a first force in a first direction and a second force in a second direction of rotation, but no significant movement of the rotor 50 takes place in a first or second rotational direction.

The shaking movement is generated by alternately acting a force or the torque in a first direction of rotation and a further force, or a further torque in a second direction of rotation, wherein the first direction of rotation is opposite to the further direction of rotation. Pauses 86 are formed between the alternating action of the forces or the torques. The length of the pauses 86 varies depending on the course of the

Process.

Further, the pauses 86 prevent a simultaneous energization of both, or all windings 56. During a break 86 in which no force or torque is generated in one direction of rotation, a force or a torque can be generated in the opposite direction of rotation. During the generation of a force, or a torque in one direction of rotation is in the

opposite direction of rotation a break 86 inserted.

The shaking motion 82 is divided into one or more sequences. According to FIG. 4, the shaking movement 82 is subdivided into three sequences 84a, 84b and 84c by way of example. During a sequence, the strength of the generated forces, or the torque and the duration of the generation of the forces or torques are substantially the same. This is achieved in that the current during a sequence substantially the same amplitude and the same

Energization time has. In particular, the energization time is 3 ms in sequence 84a and in sequence 84b the current is 5 ms

The forces or torques on the rotor 50 are during the

Energization of the windings formed. Preferably, a

Pulse modulation method used, wherein the force or the torque is formed during the pulse, and during the pulse break no force or no torque acts on the rotor. The pulse width modulated control of the first output stage or the first winding and the second output stage or the second winding are synchronized with each other. The synchronization prevents a simultaneous energization of the first and second winding. In particular, in the first sequence 84a during the energization break 90 of the first

Endstufe energized the second amplifier.

During the first sequence, in particular 35 times a force or a torque of the first direction and in particular 35 times a force, or a torque acts in the second direction of rotation. The current is applied in particular for one to 10 ms, preferably 3 ms. According to one embodiment, the number of action of the force is not set to 35. During the first sequence 84a, a rapid shaking movement should take place. The first sequence 84a is followed by the second sequence 84b. In the second sequence 84b, the pulse length or the length of the energization or the length in which a force or a torque acts on the rotor 50 is increased. The pulse length or the length of the current supply is in this case in particular 3-15 ms, preferably 5 ms. The pause between the pulses is in particular 10-50 ms, preferably 20 ms. The second sequence is followed by the third sequence 84c. In the third sequence 84c, the force or the torque acts on the rotor 50 over a longer period of time than in the two sequences 84a, 84b beforehand. In particular, windings are energized for 100-1000 ms, preferably 300 ms. It is thus for the period of energization, a force or torque on the rotor 50. Between the pulses, in particular the Bestromungsimpuls, which leads to the formation of a force or a

Torque on the rotor leads is formed a break 86. The break is special between 10 and 100 ms, preferably 20ms.

Furthermore, between the individual sequences 84a, 84b and 84c

Sequence pauses be formed. In the sequence pauses no

Energization and it thus forms no force or torque acting on the rotor 50 from.

The amount of force or torque is increased by lengthening the pulse. The force or torque and the duration of the training the force or the torque on the rotor 50 varies between the individual sequences. According to Figure 4, the Bestromungsimpuls and thus the force or torque is increased from sequence to sequence.

The number of generated forces or torques acting on the rotor 50 will be less from sequence to sequence, while for example according to FIG. 4 in the first sequence 84A still 35 pulses per direction of rotation are generated, in the second sequence 84b only each generates 5 pulses. In the third sequence 84c, only a single pulse is generated in each case. If the first impulse already leads to a solution of the rotor, the vibrating motion 82 according to the invention consists only of a single impulse. In particular, as the number of sequences increases, the number of forces or torques generated decreases, but the duration of the effect increases.

If, after a first shaking movement 82, no blocking solution has taken place, the shaking movements 82 are repeated as often as desired. Between the Rüttelbewegungen 82 Rüttelpausen 88 are formed, wherein in the

Rüttelpausen 88 no force or no torque acts on the rotor 50. The Rüttelpausen 88 serve to cool the stator 50, in particular the

Windings and the power amplifiers. At the beginning, the Rüttelpausen 88 may be smaller, since in particular at a restart, the pump 1 is cold. With increasing jogging movement 82, however, the pump 1 is heated.

In particular, the windings and the final stage are heated. To prevent damage to the windings and the power amplifiers are pauses inserted. By way of example, the first jolting interval 88 lasts one second between the first and second jogging movements, whereas the second jogging pause already lasts 5 seconds, the 3 further pauses for 10 seconds, the five further pauses for 20 seconds and the 10 further pauses for pauses 88 2 minutes. According to the invention, the jarring pauses 88 may vary by the above-mentioned values.

The process is terminated immediately as soon as a rotational movement of the rotor 50 is detected. The rotational movement is detected in particular by the detection of a Hall edge of the Hall sensor 32. If a rotational movement detected so the blockage was released and the pump 1 can promote the fluid. Next the detection of the rotational movement by means of the Hall sensor 32, a detection of the rotational movement by the evaluation of the course of the

Energizing the pump 1 done. In this case, the course of the current supply, with which the windings are energized, monitored. The monitoring of the rotational movement takes place continuously during the shaking movement 82, in particular during the pauses and during the energization.

According to one embodiment of the invention, monitoring of

Rotational movement during the breaks, in particular the Rüttelpausen done

Overall, the number of repetitions of the shaking motion 82 is limited to a fixed value. If, after completion of the repetitions limited to a fixed value, no rotational movement of the motor is detected, the process is aborted and no attempt is made to start the pump 1.

The method according to the invention can also be used with pumps which do not have a claw pole stator, in particular pumps with an EC or DC drive. Also, the stator may have more than two windings.

FIG. 5 shows a further embodiment of a pump 200 according to the invention. The pump 200 includes a plurality of identical components or components having a similar function as the pump 1 of Figure 2 and 3. In particular, the components pump housing 210, seal 218, pump well 220, motor housing 230 substantially correspond to the corresponding components in Figure 2 and 3. For the operation and the interaction with other components is therefore referred to the description figures 3 and 4. The rotor 250 has a slightly different structure from the rotor 50. The rotor 250 has a magnetized part disposed inside the pump pot 220. The part of the rotor 250 carrying the magnets 251 is connected to an impeller 254 via a connecting element 253. The impeller 254 has wings that promote the fluid. The impeller promotes the fluid when turning. The inventive method according to claim 1 can be used in a pump corresponding to the other embodiment.

The stator 240 has a laminated core with a plurality of radially inwardly directed stator teeth. The stator teeth are each wound by at least one winding. To prevent the windings from slipping off, the stator teeth each have a stator head. The stator head faces towards the rotor 250. In addition, the stator head serves to enhance the guidance of the magnetic flux to the rotor 250. The stator 240 is within the

Motor housing 230 arranged. A fixing member 264 presses the stator in the axial direction in the direction of a stopper, which is formed on the motor housing 230. The fixing element 264 has for this purpose a plurality of spring element, which are each arranged around a guide pin. The fixation element will self-depress at the pump head flange 226.

On the side facing away from the pump housing of the pump 1, the electronics 260 is arranged. The electronics are protected by a cover 239. A sealing ring 237 between the cover and the motor housing 230 prevents ingress of fluids to the electronics 260.

The shaking movements 82 are generated by a corresponding generation of forces or torques in a first or a second direction of rotation. The generation of forces or torques by means of amplifiers in a bridge circuit, in particular the control of a B6 bridge. The force or the torque in one direction of rotation is here by a

Energizing, corresponding to a desired rotational movement in this

Direction of rotation generated. Preferably, the control takes place by means of a pulse width modulated current. Wherein the course of the control according to Figure 4 and the associated description is done.

The sump 220 of the further embodiment may also have a ring 29 and / or a labyrinth 27 corresponding to FIG. The functionality and training are the same.

An output stage may in particular comprise MOSFETs or transistors.

Claims

claims

1. A method for solving a blockage in a pump (1, 200),

in particular a motor vehicle pump, wherein the pump (1, 200) has a stator (40, 240) and a relative to the stator (40, 240) rotatory rotatably arranged rotor (20, 220), characterized

characterized in that, when the rotor (20, 220) is blocked, a rotary shaking movement (82) of the rotor (20, 220) is generated to clear the blockage.

2. The method according to claim 1, characterized in that the

rotary shaking movement (82) of the rotor (20, 220) by alternately acting on a force, or a torque in a first direction of rotation and a further force, or a further torque in a second, opposite to the first direction of rotation, to the rotor (20, 220) is generated.

3. The method according to claim 2, characterized in that the forces, or the torques by energizing the pump (1, 200), in particular an energization of at least one winding (46) are generated.

4. The method according to any one of the preceding claims, characterized

characterized in that the rotary shaking movement (82) is generated by a pulse-width-modulated energization of the pump (1, 200), or by a pulse-shaped energization with at least one pulse.

5. The method according to any one of claims 2 to 4, characterized in that act between the alternating forces, or

Torques pauses (86) are formed in which no force acting on the rotor (20, 220) force, or torque is generated.

6. The method according to any one of the preceding claims, characterized

characterized in that the shaking movements (82) are repeated, wherein between the shaking movements Rüttelpausen (88) are formed, wherein in the Rüttelpausen (88) no force, or no

Torque is generated on the rotor (20, 220), and that

in particular the Rüttelpausen (88) of shaking movement (82)

Shaking movement (82) will be longer.

7. The method according to any one of the preceding claims, characterized

characterized in that the shaking movement (82) is subdivided into one or more sequences (84a, 84b, 84c), during a sequence (84a, 84b, 84c) the strength of the generated forces, or the generated torques and duration of the generation of the Forces and torques are substantially equal.

8. The method according to claim 7, characterized in that the pauses (86) within a sequence (84a, 84b, 84c), in which no force acting on the rotor (20, 220) force, or torque is generated in

Are essentially the same length.

9. The method according to any one of claims 7 to 8, characterized in that between the individual sequences (84a, 84b, 84c)

Sequence pauses are inserted, in which no force acts on the rotor (20, 220).

10. The method according to any one of claims 7 to 9, characterized in that the amount of force, or the torque and the duration of the training of the force, or the torque on the rotor (20, 220) between the individual sequences (84a , 84b, 84c), in particular from sequence (84a, 84b, 84c) to sequence (84a, 84b, 84c) is increased.

11. The method according to any one of claims 9 to 10, characterized

characterized in that the number of generated forces, or

Torques that act on the rotor (20, 220) decrease from sequence (84a, 84b, 84c) to sequence (84a, 84b, 84c).

12. The method according to any one of the preceding claims, characterized by a termination of the method upon detection of a Rotational movement, in particular by means of a Hall sensor (32),

in particular the detection of a Hall edge, or on the basis of

Evaluation of a course of energization of the pump (1, 200) takes place.

13. The method according to any one of the preceding claims, characterized

characterized in that the monitoring of the rotational movement

continuously or in the pauses (86, 88), in particular the pauses (86), the pauses (88) or the sequence pauses, between the action of a force on the rotor (20, 220) is performed.

14. The method according to any one of the preceding claims, characterized

characterized in that upon detection of a blockage, the energization is interrupted and a Bestromungspause (90) is inserted, wherein following the Bestromungspause (90) with the rotary

Shaking movement (82) is started.

15. Electrical machine comprising a pump (1, 200), in particular a motor vehicle pump, with a rotor (20, 220) and a stator (40, 240) and a drive means (60) for controlling the pump (1, 200), characterized characterized in that the electrical machine performs a method according to any one of the preceding claims for releasing a detected blockage of the rotor (20, 220).