This application is a National Stage completion of PCT/EP2008/063937 filed Oct. 16, 2008, which claims priority from German patent application serial No. 10 2007 050 775.7 filed Oct. 24, 2007.
The invention concerns a motor vehicle control system for controlling a motor vehicle with a hybrid drive comprising an internal combustion engine and an electric motor.
A motor vehicle control system has a number of functional components, for example, an internal combustion engine functional component, a transmission functional component, a brake functional component and a battery functional component, such that the individual functional components acting in co-ordination ensure the correct operation of the motor vehicle. A motor vehicle control system, for controlling a motor vehicle with a hybrid drive, additionally requires a hybrid functional component.
In motor vehicle control systems known from the prior art for controlling a motor vehicle with hybrid drive, a recommended value for an operating status of the hybrid drive is generated with the help of so-termed automatic status-determining means. Owing to the number and variety of input parameters to be taken into account when determining a recommended value for the operating status of the hybrid drive, there are complex status-determining means which, on the one hand, can only be realized with much effort and expense and, on the other hand, can only be adapted or changed, again, with considerable effort and expense. Furthermore, the definition of suitable recommended values for the operating status of the hybrid drive presents difficulties.
Starting from there, the present invention addresses the problem of providing a new type of motor vehicle control system for controlling a motor vehicle with a hybrid drive comprising an internal combustion engine and an electric motor.
The motor vehicle control system, according to the invention, comprises a plurality of functional components divided into at least three sub-components, namely, a strategy sub-component, a control sub-component and an actuator sub-component, to be specific at least an internal combustion engine functional component for controlling the internal combustion engine, a transmission functional component for controlling a transmission and a hybrid functional component for controlling the electric motor and a clutch connected between the internal combustion engine and the electric motor, such that the strategy sub-component of the hybrid functional component comprises an operating status prescription module which, in order to determine a prescribed value for the operating status of the hybrid drive, reads in a first number of data from functional components, processes the read in data, in a second sub-module, in order to provide a second number of output parameters, and, in the second sub-module, determines the said prescribed value for the operating status of the hybrid drive using the said output parameters from the first sub-module with the help of an automatic status definer.
In the motor vehicle control system, according to the invention, the operating status prescription module of the strategy section of the hybrid functional component is divided into two sub-modules, the first sub-module serving to pre-process data read in and the second sub-module determining the prescribed value for the operating status of the hybrid drive using output parameters from the first sub-module and with the help of automatic status-determining means. By virtue of this division into two sub-modules of the operating status prescription module, according to the invention, a hierarchic division of the operating status prescription module is produced, whereby the structure of each sub-module can be relatively simple. Each of the sub-modules can be made, and can be modified and adapted, with relatively little effort and expense.
New input parameters, for the operating status prescription module, can be included with relatively little effort since then only the first, but not the second sub-module which includes the automatic status-determining means, has to be adapted. Moreover, the second sub-module with the automatic status-determining means can be adapted easily since it is independent of the quantity and type of the input parameters used for the operating status prescription module.
Preferred further developments of the invention emerge from the subordinate claims and from the description given below. Example embodiments of the invention, to which it is not limited, are explained in greater detail with reference to the drawing, which shows:
The motor vehicle control system 1 comprises a plurality of functional components 2, 3, 4, 5, 6 and 7 each divided into three sub-components, such that each of the functional components 2 to 7 is divided into a strategy sub-component 8, a control sub-component 9 and an actuator sub-component 10.
In the example embodiment shown in
All the functional components 2 to 7 are divided into three sub-components 8, 9 and 10 but the actuator sub-component 10, of the hybrid functional component 4, is subdivided into two part-sub-components, namely, one part-sub-component 11 for the electric motor and one part-sub-component 12 for the clutch connected between the electric motor and the internal combustion engine.
Specific tasks or functions are assigned to the sub-components 8 to 10 of the functional components 2 to 7.
Thus, the strategy sub-component 8 of each functional component 2 to 7 at least serves to determine at least one recommended value for the respective functional component 2 to 7, namely, for the control sub-component 9 of the respective functional component 2 to 7. In addition, the strategy sub-component 8 of each functional component 2 to 7 serves to determine data for influencing the strategy sub-component 8 of at least one other functional component and the control sub-component 9 of at least one other functional component.
The control sub-component 9, of each functional component 2 to 7, serves to check the, or each, recommended value provided by the strategy sub-components 8 of the respective functional components 2 to 7 and thereby to determine at least one target value for the respective functional components. In addition, the control sub-component 9, of each functional component 2 to 7, serves to determine data for influencing the strategy sub-component 8 and/or the control sub-component 9 of at least one other functional component. Furthermore, the control sub-component 9 preferably serves to feed back at least one actual parameter value to the strategy sub-component 8 of the respective functional component.
The actuator sub-component 10, of each functional component 2 to 7, at least serves to implement the, or each, target value and to feed back at least one actual parameter value to the control sub-component 9 of the respective functional component 2 to 7.
In addition to the functional components 2 to 7 divided into three sub-components, the motor vehicle control system 1 of
The strategy sub-component 8 of the hybrid functional component 4 comprises at least a torque prescription module and an operating status prescription module 17. The torque prescription module serves to determine a recommended value for the torque distribution of a torque desired by the driver between the internal combustion engine and the electric motor of the hybrid drive. The operating status prescription module 17 serves to determine a prescribed value for the operating status of the hybrid drive.
The present invention now concerns such details of the strategy sub-component 8 of the hybrid functional component 4 as relate to the determination of a prescribed value for the operating status of the hybrid drive in the operating status prescription module of the strategy sub-component 8. The structure of the operating status prescription module 17 is described in detail below with reference to
As indicated in
The data read in by the operating status prescription module 17 are the following input parameters:
It should be mentioned that the above input data to the operating status prescription module 17 constitute a preferred selection of data from the functional components of the motor vehicle control system, although the quantity and nature of the data read in by the operating status prescription module 17, which serve as input data for it, of course can be varied. From the data 18 to 21 read in from the functional components, the operating status prescription module 17 of the strategy sub-component 8 of the hybrid functional component 4 generates an output signal 22, this output signal 22 being the prescribed value for the operating status of the hybrid drive.
The said pre-selected hybrid driving condition specifies a change from the electric driving operating status to the hybrid driving operating status, but leaves open the time when and the exact manner in which the said change from the electric driving to the hybrid driving operating status is carried out, so that the control sub-component 9, to which the prescribed value 22 for the operating status of the hybrid drive is transmitted as an input signal, itself determines the time when and the manner in which the change specified by the pre-selected hybrid driving condition, between electric and hybrid driving, occurs.
According to the invention, as can be seen from
In addition to the first sub-module 27, which serves to pre-process the data 18 to 21 read in by the operating status prescription module 17, the operating status prescription module 17 of the motor vehicle control system, according to the invention, also comprises a second sub-module 29 in which, with the help of an automatic status-determining means or status-determiner, the prescribed value 22 for the operating status of the hybrid drive is determined, namely, by using the output variables 28 from the first sub-module 27.
Thus, in the motor vehicle control system, according to the invention, the operating status prescription module 17 of the strategy sub-component 8 of the hybrid functional component 4 is divided into two sub-modules such that the first sub-module 27 serves to pre-process the data 18 to 21 read in and to produce Boolean output signals 28, which are then used in the second sub-module 29 in automatic status-determining means to determine the prescribed value 22 for the operating status of the hybrid drive. As the said prescribed value 22, one of four defined operating statuses is emitted.
The structure of the operating status prescription module 17, according to the invention, allows simple adaptation and modification of the operating status prescription module 17.
Number | Date | Country | Kind |
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10 2007 050 775 | Oct 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/063937 | 10/16/2008 | WO | 00 | 4/22/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/053295 | 4/30/2009 | WO | A |
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Number | Date | Country | |
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