WO2022128601A1

WO2022128601A1 - Method and device for operating a drive train

Info

Publication number: WO2022128601A1
Application number: PCT/EP2021/084497
Authority: WO
Inventors: Paul Oborowski; Florian Schlumpp
Original assignee: Robert Bosch Gmbh
Priority date: 2020-12-16
Filing date: 2021-12-07
Publication date: 2022-06-23
Also published as: DE102020215982A1; CN116888002A; EP4263269A1

Abstract

The invention relates to a method for operating a drive train of a motor vehicle (1), the drive train comprising a first axle (3), with a first drive apparatus (5) and at least one wheel (7) operatively connected to the first drive apparatus (5), and an axle (2), with a second drive apparatus (4) and at least one wheel (6) operatively connected to the second drive apparatus (4), the first drive apparatus (5) having an electric machine (8), wherein, in range-extending operation, in the normal case the electric machine (8) is operated in a free-wheeling mode and a requested drive torque is provided by the second drive apparatus (4). According to the invention, in a special case in which at least one wheel-specific traction limit of the at least one wheel (7) of the second axle (2) is currently exceeded or is expected to be exceeded during the range-extending operation, a specified portion of the requested drive torque is provided by means of the electric machine (8).

Description

description

title

Method and device for operating a drive train

The invention relates to a method for operating a drive train of a motor vehicle, the drive train having a first axle with a first drive device and at least one wheel operatively connected to the first drive device and a second axle with a second drive device and at least one wheel operatively connected to the second drive device. wherein the first drive device has an electric machine, and wherein in a range-extension operation of the drive train, the electric machine is normally operated in a freewheeling mode and a requested drive torque is provided by the second drive device.

Furthermore, the invention relates to a device for operating a drive train as described above.

State of the art

Methods and devices of the type mentioned are already known from the prior art. With the increasing electrification of motor vehicles, the type of motor vehicles that use a separate drive device for each axle is also increasing. Drive trains are known, for example, that use an internal combustion engine to drive a front wheel axle and electric machines on the rear wheel axle. All-electric motor vehicles are also known in which only electric machines are used on both a first and a second axle. Due to the limited capacity of an electrical storage device, the one or more electrical machines with electrical Supplied with energy, operating modes are used by which the range of a motor vehicle having the drive train is maximized. For example, range extension operation is known, in which a requested drive torque is converted by the electric machine on one axle, while the electric machine on another axle is switched off or deactivated and is therefore operated in a freewheeling mode. It has been found that this improves the overall efficiency of the drive train and thus the range of the motor vehicle can be increased.

Disclosure of Invention

The method according to the invention with the features of claim 1 has the advantage that the driving stability is improved with simple means in the range extension operation. According to the invention, this is achieved in that in a special case, i.e. different from the normal case mentioned above, when at least one wheel-specific traction limit of the at least one wheel of the second axle is exceeded or threatens to be exceeded, a predetermined proportion of the requested drive torque is provided by the electric machine provided. The electric machine, which is therefore normally switched off in range extension mode or is operated in freewheeling mode, is used in special cases to also provide the requested drive torque and thereby to support the second drive device in the special case in such a way that in particular the traction limits of the wheels are not exceeded . The electric machine is thus controlled to convert a predetermined portion of the requested drive torque when a wheel that is assigned to the second drive device cannot convert the requested drive torque. Overall, the requested drive torque is nevertheless made available to the driver in full, at least as a rule. In this special case, the range is reduced only slightly more than in the normal case. However, the additional loss is accepted for the continued driving stability and better traction of the motor vehicle. According to a preferred development of the invention, the electric machine is operated in a torque-neutral manner in the freewheeling mode. This means that the electric machine is driven or controlled in such a way that it exerts neither a positive nor a negative torque on the drive device or the wheels of the drive device. For this purpose, the electrical machine is optionally subjected to a low operating voltage, so that at least the drag losses of the electrical machine are overcome. If the electric machine has or is associated with a clutch, this is actuated in the freewheel mode to disconnect the electric machine from the edges so that the electric machine can be operated without current and is operated preferentially in order to further optimize the overall efficiency .

Furthermore, it is preferably provided that the electrical machine is dragged along in the freewheeling mode. The result of this is that the electrical machine remains connected to the at least one wheel assigned to it and is therefore driven by the wheel while the motor vehicle is in motion and is thereby dragged along. In this case, if the electric machine is designed as a permanently excited synchronous machine, drag losses act on the wheel connected to it.

Provision is furthermore preferably made for mechanical decoupling of the at least one wheel of the first axle in the freewheeling mode of the electrical machine. As already mentioned above, a coupling that is interposed in particular between the electric machine and the wheel of the first axle is ideal for this purpose.

Furthermore, it is preferably provided that in the special case the proportion of the requested drive torque, which is then provided or should be provided by the electric machine, is specified independently of the wheel-specific traction limits. This embodiment of the invention therefore provides that the torque component of the electric machine is determined in the special case independently of traction limits that are actually present. Provision is particularly preferably made for the requested drive torque to be divided equally between the first and the second Drive device is divided so that the proportion of the electric machine corresponds to 50% or half of the requested drive torque. This requires a simple implementation, which continues to ensure driving stability.

According to a further embodiment of the invention, it is preferably provided that in the special case the proportion of the requested drive torque provided by the electric machine is determined as a function of the wheel-specific traction limits of the wheels of the drive train that can be driven by the first and the second drive device. According to this embodiment, the traction limits are taken into account and a torque distribution or distribution of the requested drive torque to the drive devices is carried out as a function of these limits. This not only ensures that the traction limits of the wheels of the second drive device are not exceeded, but also that the traction limits of the wheels of the first drive device are not exceeded by the torque component now provided by the electric machine. In particular, the torque portion provided by the electric machine is restricted or limited as a function of the traction limits of the wheels assigned to the first drive device in order to prevent the wheels of the first drive device from exceeding the wheel-specific traction limits. As a result, the total drive torque of the motor vehicle may be reduced so that it no longer corresponds to the requested drive torque.

Furthermore, it is preferably provided that, depending on the wheel-specific traction limits of at least the second drive device, a maximum torque that can be transferred from the respective wheel to a roadway is determined, and that in the special case the proportion of the requested drive torque, which is provided by the electric machine, is dependent is specified by the difference between the requested drive torque and the sum of the maximum torques that can be set at least for the second drive device. This ensures that the torque that can no longer be deducted by the second drive device is transmitted by the first Drive device is taken over and implemented, so that the motor vehicle is the required drive torque total available.

When determining the portion of the requested drive torque, the traction limits of all the wheels of the first and the second drive device are preferably taken into account. As already mentioned above, this also ensures that the torque component of the electric machine is preferably reduced when the traction limits of the wheels connected to the electric machine are exceeded or threaten to be exceeded.

The wheel-specific traction limits are preferably determined by means of sensors, in particular by means of wheel-specific sensors of a driving stability assurance device of the motor vehicle. Conventional ESP (ESP = electronic stability program), ABS (ABS = anti-lock braking system) or ASR (ASR = anti-slip regulation) devices in motor vehicles use wheel-specific sensors to detect the occurrence or the probable occurrence of slip or loss of static friction and thus traction recognize. Speed sensors, for example, are used for this purpose. Alternatively or additionally, at least one acceleration sensor is used, which is read in by a control unit, in particular a central control unit. With the help of a model, the axle load on the front and rear wheel axles is calculated. Axle loads are proportional to traction limits, making it easy to capture traction limits. In contrast to the wheel speed sensors used by ESP systems, it is easier to record the traction limits, also because the accuracy of the measurement is not as relevant as in the ESP system. Furthermore, at least one environmental factor is preferably taken into account, which relates to the surroundings of the motor vehicle, for example a road surface, weather conditions and/or ambient temperatures of the motor vehicle are monitored and included in the determination of the traction limits. The redistribution of the required drive torque for reasons of traction is preferably provided in addition to driving stability protection devices and their interventions, so it is not a substitute for an ESP, ABS or ASR System. In particular, the traction limits are calculated using simple models or obtained by an ESP control unit of the motor vehicle.

The device according to the invention with the features of claim 10 is characterized in that it has a specially designed control unit which is designed to carry out the method according to the invention when used as intended. This results in the advantages already mentioned.

Further advantages and preferred features and feature combinations result in particular from what has been described above and from the claims. The invention will be explained in more detail below with reference to the drawings. to show

Figure 1 shows a motor vehicle in a simplified plan view and

FIG. 2 shows a flowchart to explain an advantageous

Method for operating a drive train of the motor vehicle from Figure 1.

FIG. 1 shows a motor vehicle 1 in a simplified plan view, which is designed as an electric vehicle in the present case. For this purpose, the motor vehicle 1 has two drivable axles 2 and 3, each of which has a drive device 4, 5 and at least two wheels 6 or 7 connected to the respective drive device. The wheels 6, 7 are either coupled directly to the respective drive device 4, 5, or a gear and/or a clutch are interposed. The drive device 5 of the second axle 3, which represents a rear wheel axle of the motor vehicle 1 in this exemplary embodiment, has an electric machine 8 as the drive machine. In this exemplary embodiment, the drive device 4 also has an electric machine 9 as the drive machine.

A control unit 10 controls the electric machines 8, 9 depending on a requested drive torque to drive the motor vehicle 1 and the requested drive torque through the wheels 6, 7 on off a lane. For this purpose, control unit 10 is connected to a device 11 which determines the requested drive torque and communicates it to control unit 10 . The device 11 is, for example, an accelerator pedal of the motor vehicle 1, a driving computer of an automated or autonomous driving system of the motor vehicle 1 or another actuating means by which a driver or user of the motor vehicle 1 can request or specify a drive torque.

Furthermore, control unit 10 is connected to control unit 12 of a driving stability system of motor vehicle 1, in particular an ESP system. A speed sensor 13 of the driving stability system is assigned to each wheel 6 , 7 of motor vehicle 1 and is connected to control unit 12 . The driving stability system or the control unit 12 is designed to detect slip or imminent slip of the wheels 6, 7 during operation. From this, in particular, traction limits of the individual wheels 6, 7 are determined by the control unit 10. A traction limit is understood to be the maximum torque that can be applied to the road surface by the respective wheel in the current and/or an expected driving situation. After exceeding its traction limit, a wheel begins to spin. The respective traction limit can change as a function of changing environmental and roadway conditions, independently of the torque actually applied to the respective wheel 6, 7, for example when motor vehicle 1 moves from a dry section of road to a wet section of road. If a traction limit or the maximum torque that can be deducted is exceeded, the affected wheel loses static friction with the road, so it spins and can therefore no longer transmit any additional torque and no or only reduced cornering forces for the motor vehicle.

In order to maximize the range of the electric vehicle, the control unit 10 controls the electric machines 8, 9 in a range extension mode in such a way that normally only the electric machine 9 of the axle 2 is controlled to apply a torque by means of the wheels 6 to the roadway for driving of the motor vehicle 1, while the electric machine 8 of the axle 3 is operated in an energy-efficient manner in a free-running mode. For example, the electric machine 8 is operated torque-neutral in the area of range extension operation, so that it is indeed operated as a motor, but with such a low torque that in particular frictional forces in the electric machine 8 itself or in the axle 3 as a whole are overcome and in particular by the wheels 7 no negative or positive drive torque is transmitted to the road surface.

According to an alternative exemplary embodiment, the electrical machine 8 is dragged along in the freewheeling mode, so that mechanical losses in the electrical machine 8 and the axle 3 are overcome overall by the torque provided by the electrical machine 4 .

According to a further exemplary embodiment, there is a clutch between the electric machine 8 and the wheels 7 which is opened in the freewheeling mode so that the wheels 7 are mechanically decoupled from the drive device 5 .

FIG. 2 shows a flow chart, on the basis of which an advantageous method for operating the motor vehicle 1 is described below, by means of which a loss of traction at the wheels 6, 7 is advantageously avoided.

The method is started in step S1 when the user or the device 10 requests a drive torque. In a subsequent step S2, it is checked whether or not the vehicle is in a range extension mode. The range extension mode is preferably set automatically if, for example, the capacity of an electrical energy store in the motor vehicle falls below a predetermined limit value. Alternatively, the range extension operation is set as a function of an operating mode selection by a user of motor vehicle 1 . If the range extension mode is not present (n), the process starts over. However, if the query in step S2 shows that the range extension operation is set (j), then in a subsequent query S3 checked whether the traction limit of one of the wheels 6, 7 is exceeded or threatens to be exceeded.

As previously mentioned, the wheel-specific traction limits are provided in particular by control unit 12 and are preferably continuously updated. Here, the traction limits of the wheels 6 of the front wheel axle 2 are monitored and compared with the requested torque. If the torque transmitted by the electric machine 9 to the wheels 6 is below the traction limits of the wheels 6(n), the method is continued in step S1. However, if one of the traction limits is currently being exceeded or is about to be exceeded (j), it is determined in the subsequent step S4 that a special case of range extension operation is present. In the special case, the requirement to only use the drive device 4 to generate a drive torque is lifted at least temporarily in order to prevent a loss of traction on the wheels 6 of the axle 2 . For this purpose, in step S5 a proportion of the requested torque is determined, which is to be provided by the electric machine 5 of the axle 3 . The total required drive torque is thus distributed to both axles 2, 3 and the torque provided by the electric machine 5 is subtracted from the torque to be provided by the drive device 4, which reduces the drive torque on the wheels 6 of the axle 2 and thus the respective traction limit of the wheels 6 is complied with or not exceeded. The torque provided at the wheels 6 is thus below the maximum torque that can be deducted, as a result of which a loss of traction is reliably prevented.

The portion of the drive torque that should be provided or is provided by the drive device 5 of the axle 3 can be determined in the different ways described below. According to a first exemplary embodiment, in a subsequent step S6, the proportion of the drive torque provided by the electric machine 8 is specified independently of the traction limits for the individual wheels. There is thus a fixed predetermined distribution of the drive torque to the axes 2, 3 instead. The required drive torque is particularly preferably distributed equally to both axles 2, 3 divided so that the respective drive device 4 or 5 converts or provides 50% of the requested power or the requested drive torque.

According to a further exemplary embodiment, in a step S7 following step S5, the proportion of the requested drive torque that is to be provided by the electric machine 8 is determined as a function of the wheel-specific traction limits of at least the wheels 6 of the drive device 4. By taking into account the wheel-specific traction limits, the proportion of the drive torque for the electric machine 8 can be specified in such a way that, for example, a focus is placed on an energy-efficient implementation of the special case, so that the electric machine 5, for example, only takes over the proportion of the drive torque that cannot be settled on the wheels of axle 2 in relation to the traction limits. In particular, the method provides that, depending on the wheel-specific traction limits of at least the wheels 6, a maximum torque that can be deposited on the road surface by the respective wheel 6 is determined, and that in the special case the proportion of the requested drive torque that is provided by the electric machine 8 is specified as a function of the difference between the requested drive torque and the total maximum torque that can be deducted, at least of the wheels 6 of the second drive device. In particular, the proportion of the drive torque of the electric machine 8 corresponds to the aforementioned difference. As a result, exactly the excess torque component that leads to the traction limits of the wheels 6 being exceeded is taken over by the electric machine 8 and transmitted to the wheels 7 .

The traction limits of all wheels 6, 7 of the first and second drive device 4, 5 are particularly preferably taken into account when determining the proportion of the requested drive torque for the electric machine 8. This means, for example, that the drive torque provided by the electric machine 5 can also be influenced by the traction limits of the wheels 7 . In particular, it is provided that the proportion of the drive torque that is provided by the electric machine 5 can be reduced by the traction limits or as a maximum Torque of the wheels 7 is limited if the traction limits of the wheels 7 are exceeded or are about to occur. In this case, the proportion is preferably limited independently of the requested drive torque, so that in the event that the full requested torque is not available due to existing traction limits on the wheels 6, 7

Drive torque can be sold, the total drive torque is reduced in order to maintain the traction limits.

Claims

Expectations

1. A method for operating a drive train of a motor vehicle (1), the drive train having a first axle (3) with a first drive device (5) and at least one wheel (7) operatively connected to the first drive device (5) and an axle (2) with a second drive device (4) and at least one wheel (6) that is operatively connected to the second drive device (4), the first drive device (5) having an electric machine (8), and in a range-extension operation the electric machine ( 8) is operated in a freewheeling mode and a requested drive torque is provided by the second drive device (4), characterized in that in a special case of a current or expected exceeding of at least one wheel-specific traction limit of the at least one wheel (7) of the second axle (2) during the range extension operation, a predetermined proportion of the started ordered drive torque is provided by the electric machine (8).

2. The method according to claim 1, characterized in that in the freewheeling mode, the electric machine (8) is operated torque-neutral.

3. The method according to claim 1, characterized in that the electric machine (8) is dragged along in the freewheeling mode.

4. The method according to claim 1, characterized in that in the freewheeling mode, the electrical machine (8) from the at least one wheel (7) of the first axle (3) is mechanically decoupled.

5. The method according to any one of the preceding claims, characterized in that in the special case the proportion of the requested Drive torque, which is provided by the electric machine (8), is specified independently of the wheel-specific traction limits. Method according to one of the preceding claims, characterized in that in the special case the proportion of the requested drive torque which is provided by the electric machine (8) as a function of the wheel-specific traction limits of at least the wheels (6) which can be driven by the second drive device (5) of the drive train is determined. Method according to one of the preceding claims, characterized in that as a function of the wheel-specific traction limits of at least the second drive device (4), a maximum torque that can be deposited by the respective wheel (6) on a roadway is determined, and that in the special case the proportion of the requested drive torque , which is provided by the electric machine (8), depending on the difference between the requested drive torque and the total maximum torque that can be deducted, is specified at least for the second drive device (4). Method according to Claim 7, characterized in that the traction limits of all wheels (6,7) of the first and second drive device (4,5) are taken into account when determining the proportion of the requested drive torque. Method according to one of the preceding claims, characterized in that the wheel-specific traction limits are determined by means of sensors, in particular by means of wheel-specific sensors (13) of a driving stability assurance device of the motor vehicle. Device for operating a drive train, characterized by a specially prepared control unit (10) which is designed to carry out the method with the features of one of Claims 1 to 9 when used as intended.