EP2844508A2

EP2844508A2 - Wheel drive unit for a wheel of an electrically driven vehicle, vehicle and method for operating a wheel drive unit of a vehicle

Info

Publication number: EP2844508A2
Application number: EP13729658.8A
Authority: EP
Inventors: Georg Bachmaier; Christian Bachmann; Dominik Bergmann; Matthias Gerlich; Andreas GÖDECKE; Guillaume Pais
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2012-06-15
Filing date: 2013-06-10
Publication date: 2015-03-11
Also published as: WO2013186158A3; WO2013186158A2; DE102012210130A1

Abstract

The invention relates to a wheel drive unit (4) for a wheel (2, 3) of an electrically driven vehicle (1), having an electrical machine (5) for driving the wheel (2, 3), which has a stator and a rotor, rotatably mounted on the stator, which can be connected to the wheel (2, 3) of the vehicle (1), and having an electronic control device (7) for actuating the electrical machine (5), wherein the wheel drive unit (4) has an eddy current brake (8) by means of which the rotor can be decelerated.

Description

description

Wheel drive unit for a wheel of an electrically driven vehicle, vehicle and method for operating a wheel drive unit of a vehicle

The invention relates to a wheel drive unit for a wheel of an electrically driven vehicle, with an electric see machine for driving the wheel, which has a stator and a stator rotatably mounted on the rotor, which is connected to the wheel of the vehicle, and with an electronic control device for driving the electric machine. The invention also relates to an electrically driven vehicle, namely in particular a motor vehicle, as well as a method for operating a said wheel drive unit.

The interest here applies to an electrically driven vehicle, namely preferably an electrically driven motor vehicle, d. H. an electric vehicle. It is already state of the art to provide wheel drive units separately for the wheels of the motor vehicle in such an electric vehicle, which can be embodied as wheel-near drive units or else as wheel hub motors. Both variants of the wheel drive unit serve to drive a single wheel. Thus, such a wheel drive unit can be provided for each wheel of the motor vehicle; alternatively, however, only two wheels of the motor vehicle can be equipped with one wheel drive unit, namely either the rear wheels or the front wheels.

If separate wheel drive units are used for the wheels of the motor vehicle, this results in particular in advantages with regard to driving safety, driving performance and also efficiency. In addition, it is possible to recover much of the energy when the vehicle is decelerated, due to electromotive braking of the electric machines is possible. The recovery of the energy is also called "recuperation." In this case, the kinetic energy of the respective wheel or the braking energy is converted into electrical energy, which in turn can be fed into an electrical energy store and used to charge the memory However, the electromotive braking of the wheels is not sufficient to reach the legally required deceleration values. "For this, the electric machines and thus the entire wheel drive units would have to be oversized by a multiple (approximately by a factor of 5), which, however, in terms of the available space, In order to be able to achieve the legally required deceleration values, a conventional mechanical brake is additionally used in the state of the art, namely, as a rule, in the case of the wheels of the vord Such a brake is usually designed as a disk brake with a hydraulic brake circuit. A particular challenge therefore lies in being able to achieve the required deceleration values exclusively with the help of the wheel drive units used, without the need for an additional mechanical brake.

It is an object of the invention to provide a solution, as in a wheel drive unit of the type mentioned, the deceleration force can be improved compared to the prior art.

This object is achieved by a wheel drive unit, by an electrically driven vehicle, as well as by a method having the features according to the respective independent claims. Advantageous embodiments of the invention are the subject of the dependent claims, the description and the figure.

A solution according to the wheel drive unit for a wheel of an electrically driven vehicle includes an electric Machine for driving the wheel, which has a stator and a rotor rotatably mounted on the stator, which is connectable to the wheel of the vehicle. The wheel drive unit also includes an electronic control device for controlling the electric machine. According to the invention it is provided that the wheel drive unit additionally has an eddy current brake, by means of which the rotor and thus also the wheel can be braked.

The effect according to the invention is thus achieved by integrating an eddy current brake into the wheel drive unit, by means of which the rotor of the electric machine and thereby also the wheel of the vehicle can be magnetically braked. With such an eddy current brake, it is possible to generate particularly high deceleration torques, without having to use an additional, mechanical disk brake or the like. An eddy current brake is also a wear-free brake in which the eddy current losses are used for braking the rotor. For this purpose, only one - in particular inhomogeneous - magnetic field must be generated, due to which eddy currents are induced in the rotor or an additional disk connected to the rotor. In the wheel of the vehicle - and in particular in all wheels of the vehicle - thus no additional mechanical brake needs to be used, so that the total use of such a brake with the associated hydraulic brake system and the associated disadvantages is unnecessary. Thus, therefore, no additional electrical auxiliary consumers (such as a pump) are required because the eddy current brake can be powered by the existing power electronics of the electric machine with energy. Compared to mechanical braking systems, the eddy current brake is also completely wear-free. Another advantage of the wheel drive unit according to the invention is that the control of the entire braking operation of the vehicle can also be done via the electronic control device of the electric machine, so that the external or from a vehicle side Control unit transmitted braking torque default internally in the wheel drive unit either via the electromotive braking or via the eddy current brake can be implemented. Thus, for example, the eddy current brake can only be activated when the braking torques during electromotive braking are no longer sufficient to implement the external braking torque specification. It can even be provided that the electromotive braking can take place parallel to time and thus simultaneously with the braking by means of the eddy current brake. For this purpose, the existing power electronics need only be slightly modified.

In one embodiment it can be provided that the eddy current brake has a disc formed of a metallic material, which is rotatably connected to the rotor and in which eddy currents are generated for braking the rotor. With such a disk, it is possible to generate the eddy currents on a relatively large area and thus also to provide relatively large braking torques. Such a disk may extend in the radial direction perpendicular to a rotational axis of the rotor. It can be arranged and fixed on a shaft of the rotor and, in particular, can be of circular design. The arrangement of the disc perpendicular to the axis of rotation of the rotor ensures that this disc is axially accessible both from one side and from the other axial side for magnetic fields, which in turn is very favorable for the arrangement of electromagnets.

The eddy current brake preferably has at least one electromagnet, which is designed to generate a magnetic braking force. With regard to the electromagnet, two different embodiments can now be provided:

On the one hand, it can be provided that the at least one electric magnet is a magnet of the stator of the electric machine, which is also designed to drive the rotor. In this embodiment, therefore, a magnet which is present anyway in the case of the electric machine is also used for the function of the eddy current brake, so that the use of an additional electromagnet is unnecessary.

Alternatively, however, it can also be provided that the at least one electromagnet of the eddy current brake is a magnet which is separate from the electromagnet of the stator. This embodiment has the advantage that the electromagnet can advantageously be placed at a small distance from said disk and the arrangement of the electromagnet is thus not limited to the drive-specific arrangement of the stator. Thus, even greater braking torques or braking forces can be generated with the eddy current brake. The electromagnet may in this embodiment be arranged so that the magnetic flux generated by means of this electromagnet is perpendicular to the said disc. The electromagnet can thus have two core legs, which can be arranged on the opposite sides of the disk and can both point in the axial direction of the disk, so that the electromagnet engages around the disk virtually on both sides.

Preferably, the control device of the electrical machine is also designed to control the eddy current brake. This means that using the same electronic control device - such as a microcontroller - both the electric machine and the eddy current brake can be controlled. The internal control device of the wheel drive unit thus assumes two different functions, namely on the one hand the function of driving the electric machine and on the other hand, the function of driving the eddy current brake. With one and the same microcontroller, which can be used as a control device, thus several components can be controlled.

It proves to be particularly advantageous if the eddy current brake is supplied or controlled via one and the same power electronics, via which the electrical Machine is supplied with electrical energy. In the power electronics, an electrical DC link can be provided, in which an electrical DC link voltage is provided to a DC link capacitor. This voltage can then serve both to supply the eddy current brake and to supply the electric machine. For example, the common power electronics include an inverter, which can provide an alternating voltage for the electrical machine from the intermediate circuit voltage. This inverter can also be used to generate an electrical AC voltage for the eddy current brake. The number of components used is thus reduced to a minimum.

The control device may have an interface for communication with an on-board vehicle control device. The control device may then be designed to receive both drive control commands relating to the driving of the wheel and brake control commands with respect to the control of the eddy-current brake via this interface. Consequently, an already existing interface can be used in order to be able to transmit control commands relating to the control of the eddy-current brake to the control device. The control device thus does not need to be reconfigured in a complex manner, but it can be used already existing control devices.

The electric machine is preferably a permanent magnet-excited synchronous machine. In such a machine, the rotor can carry permanent magnets, while the stator can have a stator winding with, in particular, three phase phases.

The wheel drive unit is preferably a hub drive unit or a hub motor. Alternatively, it can also be used as a wheel-like drive unit. The invention also relates to an electrically driven vehicle, in particular motor vehicle, with a wheel and with a wheel drive unit according to the invention, which is designed to drive the wheel.

In the vehicle can be provided that waiving a separate from the wheel drive unit mechanical brake, the wheel is braked exclusively by means of the wheel drive unit, and in particular exclusively by means of the eddy current brake and / or electric motor. It is therefore unnecessary to use a mechanical brake with the associated disadvantages in terms of wear, space and cost. An inventive method is used to operate a

Wheel drive unit of an electrically driven vehicle, wherein by means of an electric machine of the wheel drive unit, a wheel of the vehicle is driven and the electric machine has a stator and a stator rotatably mounted on the rotor, which is connected to the wheel, and wherein by means of an electronic control device Wheel drive unit, the electric machine is controlled. By means of an eddy current brake of the wheel drive unit of the rotor and thus the wheel of the vehicle is braked.

The preferred embodiments presented with reference to the wheel drive unit according to the invention and their advantages apply correspondingly to the vehicle according to the invention and to the method according to the invention.

Further features of the invention will become apparent from the claims, the figure and the description of the figures. All the features and feature combinations mentioned above in the description as well as the features mentioned below in the description of the figures and / or in the figures alone, and

Feature combinations can be used not only in the specified combination, but also in other combinations or in isolation. The invention will now be described with reference to a preferred embodiment, as well as with reference to the accompanying drawings. The single figure illustrates in schematic representation a vehicle according to an embodiment of the invention.

A in the figure in a schematic and highly abstract representation shown vehicle 1 is in the embodiment, an electrically powered vehicle, namely in particular a passenger car. The vehicle 1 is known to have four wheels on, namely two front wheels 2 and two rear wheels 3. In the exemplary embodiment, a separate wheel drive unit 4 is provided for each wheel 2,3, which so well for driving and for braking the respective wheel. 2 , 3 is formed. Alternatively, it can also be provided that only the front wheels 2 or the rear wheels 3 each such wheel drive unit 4 is assigned, so that a total of only two such units are provided.

The wheel drive units 4 can, for. B. wheel hub motors Alternatively, the wheel drive units 4 so-called rad be near motors, which are not directly in the hub, but at a small distance to the respective wheel 2, 3 angeord net.

The wheel drive units 4 each have an electric machine 5, which is formed in the embodiment as a permanent magnet synchronous machine or as a so-called brushless DC motor. The electric machine 5 is known to have a rotor which is rotatably connected to the respective wheel 2, 3, and a stator, on which the rotor is rotatably mounted. While the rotor carries permanent magnets, the stator has an electrical stator winding which may comprise, for example, three phase strings. The number of phase strands is only mentioned here by way of example, and the stator winding can also be a Have number of phase strands, namely, for example, two or four. The stator winding is electrically coupled to a power electronics 6, which may have, for example, an inverter or inverter. This inverter sets an intermediate DC voltage to provide an electrical AC voltage for each phase strand of the stator winding. The power electronics 6 is controlled by means of an electronic control device 7, which may be provided for example as a microcontroller or the like.

Thus, the control device 7 controls the electric machine 5. This control takes place via the power electronics 6. The power electronics 6 may be connected to a vehicle battery not shown in detail in the figure, which can serve to supply all wheel drive units 4 in total.

The wheel drive units 4 also each have an eddy current brake 8, which serves to decelerate the respective wheel 2, 3. These eddy current brakes 8 can each have a metallic disc, which is connected to the rotor of the electric machine 5 and extends in the radial direction perpendicular to the axis of rotation of the respective rotor. The eddy current brake 8 additionally includes one or more electromagnets, which are designed to generate a magnetic field and thus to induce eddy currents in the respective disc. Each eddy current brake 8 thus has a metallic disc on the one hand and at least one electromagnet on the other hand, which is in magnetic operative connection with the disc, so that eddy currents induced in the disc and thus the rotor is braked.

Although it is shown in the figure that each wheel drive unit 4 may have such an eddy current brake 8, but may alternatively be provided that, for example, only the have front or only the rear wheel drive units each having such an eddy current brake 8.

The respective control device 7 serves both to control the respective electric machine 5 and to control the eddy current brake 8. The respective eddy current brake 8 is also supplied with electrical energy via the associated power electronics 6. Thus, no additional control units or additional power components need to be used. The respective electromagnet of the eddy current brake can namely be supplied via the power electronics 6.

The control devices 7 also each have one

Interface 9, via which the control devices 7 are electrically connected to a vehicle control unit 10. From the vehicle control unit 10, the control devices 7 control commands regarding the control of the electric machine 5 and the control of the eddy current brake 8 received. The vehicle control unit 10 can thus transmit to the control devices 7 on the one hand drive control commands, which are based on the control of the electric machine 5 and thus on the driving of the respective wheel 2, 3. On the other hand, the vehicle control unit 10 can also transmit to the control devices 7 brake control commands relating to the braking of the respective wheel 2, 3. These brake control commands may include a braking torque command, which must be implemented at the respective wheel 2, 3. This braking torque specification can implement the respective control device 7 by means of the eddy current brake 8 and / or electromotively. In this case, the eddy current brake 8 can be switched on only when the electromotive braking alone is no longer sufficient to implement the required braking torque specification of the vehicle control unit 10.

In order to achieve the legally required delay values, without having to over-dimension the wheel drive units 4 and without having to use a mechanical brake is So integrated into the respective wheel drive unit 4, an eddy current brake 8. For this purpose, a corresponding metal disc is integrated on the rotor of the electric machine 5, which is braked by a magnetic field according to the eddy current principle. The corresponding magnetic field can be generated by means of electromagnets integrated in the stator of the electric machine 5. These electromagnets can be operated by means of the already existing power electronics 6. With regard to the electromagnets can be provided that these are those electromagnets, which are always present in the electric machine 5 and which are formed by said stator winding. Alternatively, however, in each case at least one separate electromagnet can be used, which is used exclusively for the respective eddy current brake 8.

Claims

claims

A wheel drive unit (4) for a wheel (2, 3) of an electrically driven vehicle (1) comprising an electric machine (5) for driving the wheel (2, 3) having a stator and a rotor rotatably mounted on the stator , which is connectable to the wheel (2, 3) of the vehicle (1), and with an electronic control device (7) for driving the electric machine (5),

characterized in that

the wheel drive unit (4) has an eddy current brake (8) by means of which the rotor can be braked.

Second wheel drive unit (4) according to claim 1, characterized in that the eddy current brake (8) has a disk formed of a metallic material, which is rotatably connected to the rotor and in which eddy currents for braking the rotor can be generated.

Third wheel drive unit (4) according to claim 2, characterized in that the disc extends in the radial direction perpendicular to a rotational axis of the rotor.

4. wheel drive unit (4) according to one of the preceding arrival claims, characterized in that the eddy current brake

(8) comprises at least one electromagnet for generating a magnetic braking force.

5. wheel drive unit (4) according to claim 4, characterized in that the at least one electromagnet is a magnet of the stator, which is designed for driving the rotor.

6. wheel drive unit (4) according to claim 4, characterized marked characterized in that the at least one electromagnet one of

Solenoid of the stator is a separate magnet.

7. wheel drive unit (4) according to any one of the preceding claims, characterized in that the control device (7) is designed for driving the eddy current brake (8).

8. wheel drive unit (4) according to one of the preceding claims, characterized in that the electric machine (5) is associated with a power electronics (6), via which both the electric machine (5) and the eddy current brake (8) with electrical Energy can be supplied.

9. wheel drive unit (4) according to any one of the preceding claims, characterized in that the control device (7) has an interface (9) for communication with a vehicle control unit (10) and is designed to, via the interface (9) both drive control commands with respect to the driving of the wheel (2, 3) as well as brake control commands with respect to the control of the eddy current brake (8) to receive.

10. wheel drive unit (4) according to any one of the preceding claims, characterized in that the electrical machine (5) is a permanent magnet synchronous machine.

11. Wheel drive unit (4) according to one of the preceding claims, characterized in that the wheel drive unit (4) is a hub drive unit.

12. Electrically powered vehicle (1), in particular motor vehicle, with a wheel (2, 3) and with a wheel drive unit (4) according to one of the preceding claims, which is designed for driving the wheel (2, 3).

13. Vehicle (1) according to claim 12, characterized in that waiving one of the wheel drive unit (4) separate mechanical brake, the wheel (2, 3) exclusively by means of the wheel drive unit (4), in particular excluding lent by means of the eddy current brake (8) and / or electric motor, is braked.

14. A method for operating a wheel drive unit (4) of an electrically driven vehicle (1), wherein by means of an electric machine (5) of the wheel drive unit (4) a wheel (2, 3) of the vehicle (1) is driven and the electric Machine (5) has a stator and a stator rotatably mounted on the rotor, which is connected to the wheel (2, 3), and wherein by means of an electronic control device (7), the electric machine (5) is driven,

characterized in that

by means of an eddy current brake (8) of the wheel drive unit (4) of the rotor and thus the wheel (2, 3) are braked.