WO2021164815A1 - Electric motor with field enhancement - Google Patents

Abstract

The invention relates to an electric motor for a motor vehicle drive or the auxiliary units thereof, comprising a shaft (1) for torque output, the shaft (1) being connected to at least one rotor (2, 4, 12) for conjoint rotation, the at least one rotor (2, 4, 12) being operatively connected during operation to an associated stator (6, 14), and structural means being associated with the at least one rotor (2, 4, 12) in order to enforce a field enhancement in an air gap (b) between the at least one rotor (2, 4, 12) and the stator (6, 14) in the operational state of a desired magnetic flux density in the air gap (b).

Description

Electric motor with field amplification

The invention relates to electric motors for a motor vehicle or auxiliary unit drive, with a shaft for torque output, the shaft being non-rotatably connected to at least one rotor, the at least one rotor being in operation with a stator assigned to it. The invention is in particular in the field of electric motors with field amplification, for example an axial flow machine and a radial flow machine.

Electric motors / electric machines with field weakening are already known from the prior art. The field weakening takes place, for example, by forcing a phase-shifted current supply to the windings or by means of mechanical adjustment / change in the motor itself, which reduces the magnetic flux through the windings. The state without field weakening (with high induced voltages at the winding ends at a given speed) is the normal state. The field weakening is used at high speeds of the electric motor. This is used to be able to use the broadest possible speed range. Here, a voltage induced at terminals of the windings of the electric motor is limited.

However, the prior art always has the disadvantage that an activation power or other lossy activation is required for the field weakening, where in general operation the times with field weakening make up a large part of the total operating time.

It is therefore the object of the invention to avoid or at least mitigate the disadvantages of the prior art. In particular, a loss-optimized operation of the electric motor should be provided over a wide speed and torque range when considering the overall system over the entire period of use.

This object is achieved according to the invention in a device of the generic type in that structural means are assigned to the at least one rotor in order to increase the field in an air gap between the at least one rotor and the stator in the operating state of a desired magnetic flux density, in particular especially in the operating state of a torque increase to be created to force in the air gap.

In this way, an optimized operation of the electric motor can be provided.

Advantageous embodiments are claimed in the subclaims and who will be explained in more detail below.

The structural means can be prepared to be actuated on the basis of an activation energy or activation power.

The structural means can be at least one mechanical actuator. The at least one mechanical actuator can act on the at least one rotor in order to bring about an adjustment of the at least one rotor closer to the stator in the operating state of the desired magnetic flux density.

According to one example, the electric motor can be an axial flux machine. The at least one rotor can have two rotors. The rotors can each be mounted axially displaceably between a first position and a second position. The stator can be located between the two rotors and surround the shaft.

The stator and the rotors can each form the air gap to one another. The air gap can be minimal in the first position and maximal in the second position.

The axial flux machine can be designed so that the rotors can be displaced relative to one another by a force applied from the outside (by the structural means) in order to reduce at least one of the two air gaps and to provide a higher magnetic flux between the rotor and stator during operation.

The structural means can be electrically operated coils. The coils can be arranged on the at least one rotor in such a way that, in the operating state of the desired magnetic flux density, an additional magnetic field is generated between the at least one rotor and the stator, which causes the field amplification. According to a further example, the electric motor can be a radial flux machine. Pole caps of the rotor can each be provided with a magnet. The stator can surround the rotors. The air gap can be formed between the stator and the respective magnets of the pole caps. The electrically operated coils can be located around the pole caps. The coils can be designed to generate an additional radial magnetic flux during operation of the radial flux machine in order to provide a higher magnetic flux between the rotor and stator.

According to yet another example, an axial flow machine is provided. The axial flow machine includes a shaft. The axial flux machine also includes two rotors. The rotors are connected to the shaft or are kop pelt with it. The rotors surround the shaft. The rotors are each axially displaceable between a first position and a second position. The axial flow machine further comprises a stator. The stator is located between the two rotors. The stator surrounds the shaft. The stator and the rotors each form an air gap to one another. The respective air gap or its width is mini times in the first position. The respective air gap or its width is maximum in the second position.

The axial flux machine is designed such that the rotors can be displaced relative to one another by an externally applied force in order to reduce at least one of the air gaps and to provide a higher magnetic flux between the rotor and stator during operation.

In particular, the externally applied force can act on one and / or the other rotor in a certain period of time of increased torque requirement in order to increase the magnetic flux between the rotor and stator and thus the torque requirement, for example at least twice (or three times or four times) as high as in normal operation of the axial flow machine.

In this way, an optimized operation of the axial flow machine can be provided.

The rotor can be understood as the rotating part of an electric motor and can have permanent magnets. The stator can be understood as the stationary part of an electric motor and have coil windings. The wave can be used as a elongated cylindrical and rotating machine element are understood, which is used to transmit rotary movements and torques. The axial flow machine can also be understood as a transverse flow machine.

The magnets used herein can consistently be permanent magnets, which occur in different designs and are designed for the respective purpose.

The rotors can each be connected to the shaft in a radially fixed manner without play. The shaft can also have a guide on its circumference. The guide can extend along the axis of rotation of the shaft. The rotors can be connected to the shaft via the guide. The rotors can thus be connected to the shaft in a rotationally fixed manner.

Furthermore, the rotors can be designed as rotor blades, for example circular rotor blades. Corresponding permanent magnets can be arranged on the rotor blades, which interact with the magnetic flux coming from the stator in order to make the rotor rotate about an axis. The axis can be the axis of rotation of the shaft.

The stator can, for example, be separated from the shaft by means of a bearing or it can be surrounded and supported by the shaft.

The externally applied force can point in the axial direction so that the rotors approach each other. This external force allows the rotors to move towards one another.

In this way, a defined force can be set in the axial direction.

One of this externally supplied force can counteract another force. This force can be provided by a spring element. The axial flow machine can thus have a spring element. The axial flow machine can furthermore have a first limiter. The limiter can be connected to the shaft. The spring element can be designed, the rotors in the axial direction in the second Po- position to press. Furthermore, if there is no externally applied force, the spring element can be designed to hold the rotors at the second position defined by the first limiter.

Thus, a force provided by the spring element for locking the rotors or rotor blades at the second position can be provided in order to provide a defined distance between the rotor / rotors and the stator for a speed range in normal operation.

For example, the first position can be defined by a maximum compression of the spring element.

As a result, a further delimiting element for the first delimiter can be omitted.

In a further example or in addition, the first position can be defined by a second limiter. The second limiter can be permanently connected to the shaft or be part of it.

With this additional limiting element, the air gap and thus also the torque to be achieved can be set very precisely.

Furthermore, the spring element can at least partially be a sleeve for the guide or surround it. This can also apply to the spring element with respect to the two th limiter. In particular, the spring element can rest against the second limiter and cause a force between the second limiter and one of the rotors. For this purpose, a further spring element can be present which brings about a force between the second limiter and the other of the rotors. The spring element and the further spring element thus act away from the second limiter, in the direction of the respective rotors.

The axial flow machine can further comprise a bearing. The bearing can interact with at least one of the rotors in order to transmit the externally applied force to the rotors. In this way, an externally predetermined force can be transmitted to the Ro gates with low friction in order to achieve the torque to be achieved.

Furthermore, a phase-shifted current can be applied to the windings of the stator in such a way that the externally applied force on the rotors results from an increased magnetic flux produced by the stator. This can also be combined with the bearing defined above, so that a mechanical and electrical force can be used to reduce the air gap.

According to an additional example, a radial flow machine is provided. Unless otherwise described, the following components have the same or similar definition / functionality as described for the axial flow machine. The radial flux machine includes a shaft. The radial flux machine further comprises a rotor. The rotor is connected to the shaft. The pole caps of the respective rotors are provided with one or more magnets. The radial flux machine also includes a stator. The stator surrounds the shaft. The shaft can interact with the stator by means of a suitable bearing. An air gap is formed between the stator and the respective magnets of the pole caps. There is an electrically operated coil around the pole caps. The electrically operated coil is designed to generate an additional radial magnetic flux during operation of the radial flux machine in order to provide a higher magnetic flux between the rotor and the stator.

In this way, an optimized operation of the radial flow machine can be provided.

The air gap can be defined in such a way that it is the distance between one of the pole caps of the rotor and the stator when these are directly opposite each other, for example during operation, and thus have a shortest distance.

In the special case of a requirement for a higher torque than in normal operation, the coil can be operated or switched on. For example, the higher required torque can be at least twice, three times, four times, five times, six times or ten times as high as a torque in normal operation. Normal operation can be understood as an operation with no load connected to the drive. This can also apply to the axial flow machine described above.

The operation of the electric motor can thus be adapted as a function of the situation without experiencing excessive losses in normal operation.

In an advantageous embodiment, the respective magnets, for example permanent magnets, can be smaller than 1/2 (or 1/3 or 1/4 or 1/5) of a width of the air gap.

In this way, costs for the permanent magnets, which are relatively expensive in contrast to coils, can be saved.

In particular, one winding of the coil can bear against the respective magnet. The magnet can also be surrounded by the winding of the coil.

This makes it possible to reduce a force deviation when defining the required torque.

In other words, the invention relates to a permanent magnet synchronous motor (PMSM) electric machine with field amplification.

An electric machine with field weakening can also be provided, in which, however, the normal state (without active adjustment / influencing) is operation with reduced magnetic flux through the coils.

During times with increased torque demand, the magnetic flux through the coils can be selectively increased by means of active adjustment / influencing of the motor (operation with field strength). Since the operating times with increased torque requirement only make up a small proportion of the total operating time, any additional losses due to an active field strengthening only have a small influence on the total losses. On the one hand, a design with mechanical adjustment / influencing of the magnetic flux can be provided. This design can be an axial flow machine with two rotors, which are arranged to the right and left of a central stator. The windings for generating an electromotive force (torque) / power of the electric machine can be arranged on the stator.

The rotors can be rotatably mounted on a shaft but displaceable in the axial direction bar. The area in which each rotor can be moved in the axial direction on the shaft can be limited by means of fixed stops. Fixed stops can limit the approach to the stator and ensure a minimum air gap.

Further fixed stops can limit the maximum distance to the stator and limit the air gap distance to a maximum value.

A spring (or several springs) can push the rotors apart (away from the stator) against the “Max” fixed stops, which limit the maximum air gap distance. The spring can act against the attractive forces between the stator and the permanent magnets on the rotor. The spring can be designed in such a way that it is stronger than the forces of attraction, so that a maximum air gap is established without the action of additional forces (e.g. by an actuator) (normal operation / rest position without field strength).

Due to the wide air gap, the magnetic flow through the stator and the stator windings can be low. In this normal operating mode, the electric machine can be suitable for higher speeds, but only generate a limited torque.

Only when a further force (right and left control force in the longitudinal direction) acts on the rotors can they move in the direction of the stator, so that the air gap distance decreases and the magnetic flux through the coils increases.

The effect of this additional force can bring about an active field strengthening in the electrical machine, so that higher torques can be achieved. Due to the Increased magnetic flow, losses due to magnetic reversal, eddy currents, etc. can increase.

As soon as the control forces (right and left control force in longitudinal direction) are reduced again, the spring force can exceed the magnetic forces of attraction between rotor and stator, so that the rotors are pressed back against the “Max” fixed stops (right and left).

With a suitable design of the spring in relation to the magnetic forces, so that the spring force is only to a limited extent stronger than the magnetic attraction forces, the control forces on the right and left can be made significantly weaker.

The control forces on the right and left can be generated e.g. by means of mechanical actuators that act on the rotors via axial bearings. With a suitable design, for example, an increased current supply to the stator windings with a suitable phase position can increase the force of attraction between the rotor and stator and thus overcome the spring force. This variant has the advantage that no separate actuator is required to activate the field strength.

If the control forces Re and Li are applied independently of one another, the field can be strengthened in two stages. Alternatively, with path-controlled control forces on the right and left, the field amplification can also be controlled more finely.

On the other hand, an embodiment with an electrical influence on the magnetic flux can be provided. This embodiment can be a radial flux machine with a rotor with permanent magnets and a stator with stator windings.

The permanent magnets on the rotor can be designed specifically for a low field flow through the stator windings.

This means that the magnets only allow operation with reduced torque generation. For this, the electric machine can be operated at high speeds with reduced losses (e.g. eddy currents, magnetic reversal, etc.) and without field weakening. Furthermore, the costs for the expensive permanent magnets are reduced. Furthermore, the rotor can have windings which are arranged in such a way that they can amplify the magnetic field generated by the permanent magnets (field amplification). For example, each permanent magnetic pole has a winding surrounding its main magnetic flux.

For times with high requirements for the torque of the electric machine, the rotor windings can be controlled electrically in a targeted manner, so that the magnetic flow through the stator windings is increased. This brings about a targeted field enhancement.

Designing the magnets for only a limited magnetic flow through the stator windings can make it possible to make the magnets significantly thinner than in the prior art. The thinner magnets also have the advantage of a reduced magnetic resistance for the magnetic flux. This results in higher flux densities with the same magnetic excitation from the current in the windings. Higher flux densities allow higher torques during field strengthening.

If it means in the present case that a component is "connected" to another component, this can mean that it is directly connected to it; It should be noted here, however, that a further component can lie in between. If, on the other hand, it means that a component is "directly connected" to another component, this is to be understood as meaning that there are no further components in between.

Even if some of the aspects described above were described in relation to the electric motor, these aspects can also apply to the axial flow machine and the radial flow machine. The aspects described above in relation to the axial flow machine and the radial flow machine can equally apply to the electric motor in a corresponding manner.

The invention is explained below with the aid of drawings. Show it:

FIG. 1a shows a schematic representation of an axial flow machine; FIG. 1 b shows a schematic representation of a field intensification in the axial flow machine; and

Figure 2 is a schematic representation of a radial flow machine.

The figures are only of a schematic nature and are used exclusively for understanding the invention. The same elements are provided with the same reference symbols. The features of the individual embodiments can be interchanged with one another.

In addition, spatially relative terms such as "below", "below", "lower" / lower "," above "," upper "/" upper "," left "," left / left ”,“ right ”,“ right / right ”and the like, are used to simply describe the relationship of an element or structure to one or more other elements or structures shown in the figures are shown. The spatially relative terms are intended to include other orientations of the component in use or in operation in addition to the orientation shown in the figures. The component can be oriented differently (rotated 90 degrees or in a different orientation), and the spatially relative descriptors used here can also be interpreted accordingly.

The electric motor will now be described with reference to embodiments in relation to the axial flow machine and the radial flow machine.

FIG. 1a shows a schematic representation of an axial flow machine. The axial flow machine comprises a shaft 1, which is connected to the drive and is therefore responsible for the transmission of the force. The axis of rotation Rx, which represents the axis of rotation of the shaft 1, runs along a longitudinal direction of the shaft 1. Furthermore, a direction of the rotation axis Rx is also defined as an axial direction x. The axial flux machine also includes a left rotor 2, which can be seen in the arrangement and has a left rotor magnet 3. Furthermore, the axial flow machine comprises a rotor on the right 4, which has a rotor magnet on the right 5. The rotors on the left 2 and right 2 are in this case via a guide (not shown) of the shaft 1, which is shown in FIG runs in the axial direction x, connected to the shaft 1 in a twisted manner. Thus, a force of the rotors left 2 and right 4 can be transmitted to the shaft.

A stator 6 with stator windings of the axial flux machine is located between the left rotor 2 and the right rotor 4. Between the rotor left 2 and the stator 6 with stator windings or the rotor magnet left 3 and the stator 6 with stator windings, as well as the rotor right 4 and the stator 6 with stator windings or the rotor magnet right 5 and the stator 6 with stator windings there is an air gap b. According to the present invention, the air gap b is reduced from a first to a second position if necessary in order to generate a field strength and to meet high torque requirements.

Furthermore, the axial flow machine comprises spring elements 7, which each exert a force on the left rotor 2 and the right rotor 4, which is directed away from the stator 6 with stator windings. The direction of action of the two spring elements 7, which can also be a single spring element 7 around the shaft 1, is directed such that the rotors left 2 and right 4 are pushed away from each other (in FIG. 1 a to the left and right).

The maximum air gap air gap b is defined by a left fixed stop Max left 10 and a right fixed stop Max right 11 with respect to the respective rotor left 2 and rotor right 4. The fixed stops mentioned in relation to the figures are limiters that allow freedom of movement in the axial direction (the only way to move the rotors left 2 and right 4) be limited to one area. A minimum air gap b is defined by a left fixed stop Min left 8 and a right fixed stop Min right 9 with respect to the respective rotor on the left 2 and the rotor on the right 4. The fixed stops (8, 9, 10, 11) can be used as a concentric form around the Shaft be attached or single or several rigid elements connected to the shaft 1.

The spring elements 7 cause a force in the direction of the fixed stop Max left 10 or the fixed stop Max right 11, the spring elements 7 each pressing the rotor left 2 against the fixed stop Max left 10 and the rotor right 4 against the fixed stop Max right 11. The fixed stop Min left 8 and the fixed stop Min right 8 can be designed as a single part. Here, the part can concentrically surround a part of the spring element 7 and thus limit a path of the rotors between the respective fixed stops Min 10 / Max 11 and the stator. Thus, the fixed stops 8 and 9 are spacers for the rotors 2 and 4 left and right, so that the rotors 2 and 4 do not come into contact with the stator 6 and a defined torque can be applied.

FIG. 1a shows the state if there is no external force acting on the rotors. In FIG. 1 b, the influence of an externally added force is described based on FIG. 1 a.

Further details and aspects are mentioned in connection with the embodiments described above or below. The embodiment shown in FIG. 1a may have one or more optional additional features that correspond to one or more aspects that are mentioned in connection with the proposed concept or embodiments described below with reference to FIGS. 1b and 2.

Figure 1b shows a schematic representation of a field strengthening in the axial flow machine. A force which can act mechanically and electromechanically on the rotors on the left 2 and right 4 is applied to the rotors on the left 2 and right 4 against the force of the spring elements 7. Here, the spring elements 7 are compressed and the air gap b between the stator 6 and the respective rotors left 2 and right 4 is reduced.

The rotors left 2 and right 4 change their axial position from the respective fixed stops Max 10 and 11 in the direction of the fixed stops Min 8 and 9. The force or forces F1 and F2 acting from the outside on the rotors left 2 and right 4 must be Exceed the spring force of the spring elements 7. A force F1 can also be applied to just one of the spring elements 7 in order to achieve a predetermined torque. The externally acting forces F1 and F2 can on the one hand be transferred to the rotors on the left 2 and right 4 via a bearing. carried out mechanical actuation and on the other hand via a phase-controlled actuation of the stator windings of the stator 6.

Further details and aspects are mentioned in connection with the embodiments described above or below. The embodiment shown in Fig. 1b may have one or more optional additional features that correspond to one or more aspects that are in connection with the proposed concept or one or more above (z. B. Fig. 1a) or below (z B. Fig. 2) described embodiments are mentioned.

Figure 2 shows a schematic representation of a radial flow machine. The radial flow machine comprises a shaft 1, which runs along an axis of rotation Rx, and a rotor 12 connected to the shaft 1. The rotor 12 has several pole caps, each of which is equipped with rotor magnets 13. In particular, the individual pole caps have rotor windings 15 which are provided for providing an additional magnetic flux.

Flier by one hand, the air gap width b can be increased by the corre sponding rotor magnets 13 are reduced. This is shown by the rotor thickness d in FIG.

On the other hand, the rotor 12 can be enlarged in its circumference or its pole caps can be enlarged. The air gap b can maintain its width in this case, the respective rotor magnets 13 being designed correspondingly smaller.

This is achieved in that the coil or its rotor windings 15 is / are electrically operated via a circuit and thus the rotor magnets 13 can be made smaller. Furthermore, when the radial flow machine is in operation, additional current can be provided when a higher torque is requested, in order to be able to provide this for the intended time of the higher torque. Reference list

1 wave

2 rotor on the left

3 magnets of the rotor on the left

4 rotor right

5 magnets of the rotor on the right

6 stator

7 spring elements

8 Fixed stop min left

9 Fixed stop min right

10 Fixed stop max left

11 Fixed stop max right

12 rotor

13 rotor magnets

14 stator

15 rotor windings

Rx axis of rotation x axial direction b air gap width

F1 control force left

F2 control force on the right d magnet thickness

Claims

Claims

1. Electric motor for a motor vehicle, motor vehicle, drive or its Nebenaggre gate, with a shaft (1) for torque output, wherein the shaft (1) is at least rotatably connected to a rotor (2, 4, 12), the at least ei ne rotor (2, 4, 12) is in operation with a stator (6, 14) assigned to it, characterized in that structural means are assigned to at least one rotor (2, 4, 12) in order to strengthen the field in an air gap (b) between the at least one rotor (2, 4, 12) and the stator (6, 14) in the operating state of a desired magnetic flux density in the air gap (b).

2. Electric motor according to claim 1, characterized in that the structural means are prepared for actuation due to an activation energy or activation power.

3. Electric motor according to claim 1 or 2, characterized in that the structural means comprise at least one mechanical actuator which acts on the at least one rotor (2, 4, 12) in order to adjust the at least one rotor (2, 4, 12) to force closer to the stator (6, 14) in the operating state of the desired magnetic flux density.

4. Electric motor according to claim 3, characterized in that the electric motor is an axial flux machine, wherein the at least one rotor (2, 4), two rotors (2, 4), the rotors (2, 4) each axially displaceable between between a first position and a second position, the stator (6) being located between the two rotors (2, 4) and surrounding the shaft (1), the stator (6) and the rotors (2, 4) each form the air gap (b) to each other, which is minimal in the first position and maximal in the second position, and wherein the axial flow machine is designed so that the rotors (2, 4) are created by an externally created by the structural means Strength are displaceable in order to reduce at least one of the two air gaps (b) and to provide a higher magnetic flux between rotor (2, 4) and stator (6) during operation.

5. Electric motor according to claim 4, characterized in that the externally applied force points in the axial direction, so that the rotors (2, 4) approach each other.

6. Electric motor according to claim 4 or 5, characterized in that the axial flux machine comprises a bearing which cooperates with at least one of the rotors (2, 4) in order to transmit the externally applied force to the rotors (2, 4).

7. Electric motor according to claim 1 or 2, characterized in that the structural means are electrically operated coils (15) which are arranged on the at least one rotor (2, 4, 12) so that in the operating state of the desired magnetic flux density additional magnetic field between tween the at least one rotor (2, 4, 12) and the stator (6, 14) is generated, which causes the field amplification.

8. Electric motor according to claim 7, characterized in that the electric motor is a radial flux machine, wherein pole caps of the rotor (12) are each provided with a magnet (13), the stator (14) surrounding the rotors (12), with between the stator (14) and the respective magnet (13) of the pole caps of the air gap (b) is formed, with the electrically operated coils (15), which are formed during operation of the radial flux machine, an additional radial one around the pole caps Generate magnetic flux in order to provide a higher magnetic flux between rotor (12) and stator (14).

9. Electric motor according to claim 7 or 8, characterized in that when a requirement for a higher required torque than normal operation, the coils (15) are operated.

10. Electric motor according to claim 8 or 9, characterized in that the respective magnets (13) are smaller than 1/2 of a width of the air gap (b).